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* As it is more costlier to deploy solar panels on water than on the land, the power produced per square meter of the material used is of greater importance ad it is high for crystalline cells.
* As it is more costlier to deploy solar panels on water than on the land, the power produced per square meter of the material used is of greater importance ad it is high for crystalline cells.
* On the whole energy efficiency is always high for a floating panel than the terrestrial one.
* On the whole energy efficiency is always high for a floating panel than the terrestrial one.
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=== H2O saving simulation ===
=== H2O saving simulation ===

Revision as of 01:28, 22 January 2017

Introduction

This section includes journal paper review for a project aimed at design and implementation of floating solar PV system (Flotovoltaics) for potential areas such as California Aqueduct, adding towards a sustainable practice of saving water and aquatic life. The need for floatovoltaics arrrises in places with water deficit or deal with land use issues such as in populous places. Various subsections under this are explained with highlights and key points which may be useful in designing this work.

H2O cooling function of Solar PV (Floatovoltaic)

Enhancing the performance of photovoltaic panels by water cooling[1]


  • P-V Characteristics are dependent on the temperature and output voltage of solar panel and are inversely proportional to each other
  • When temperature starts increasing the efficiency to produce electricity for the same irradiance level decreases
  • Performed many experiments using water and air as a coolant for cooling the solar panels and analyzed that water is the best and cheap coolant
  • Developed heating rate and cooling rate mathematical model to find the exact moment when cooling needs to start for the cooling process

Assessment of the Operating Temprature of Crystalline PV Modules Baesd on Real Use Conditions[2]

  • Found the optimal operating mode for converting electrical energy from solar panels
  • Created standard operating procedure using P-V characterstics
  • Given the results that electricity production depends on ratio of voltage/ volatge at maximum power point

Improving of the photovoltaic / thermal system performance using water cooling technique[3]

  • The cooling of PV panels is done by water circulating at PV module rear surface.
  • A mathematical modeling has been carried out to compare with the experimental set up.
  • The cooling of PV module is done by using a heat exchanger and cooling fan.
  • Different cases has been studied by changing the mas flow rate of fluid and Maximum ambient temperature MAT.

Experimental evaluation of the performance of a photovoltaic panel with water cooling[4]

  • Rear cooling of PV Module has been performed to decrease the cell temperature and increase the efficiency.
  • Graph for power output vs irradiance for both normal and hybrid model has been plotted.
  • Reduction in temperature with change in the mass flow rate has been studied.

Study on performance enhancement of PV cells by water spray cooling for the climatic conditions of Coimbatore, Tamilnadu[5]

  • Solar irradiance for the particular site has been calculated for the year.
  • Based on irradiance the PV module back and rear temperature has been calculated through a mathematical modeling.
  • Mathematical calculation for the time taken(t) for the cooling of panels at different flow rate has be derived.
  • Along with cooling of PV modules how the thin layer of water reduces the reflection losses and cleans PV panels for better efficiency.

Simulation of PV System

Design Parameters of 10kW Floating Solar Power Plant[6]


  • The paper describes the importance and advantages of floating solar power plant
  • Reduction of evaporation (70%) and algal bloom, viable in parts of India where land acquisition is problem
  • Parts of the system: solar PV module, string inverter, module mounting structure, cable and connectors, FRP floating platform, mooring arrangement, access gangway and electrical installations
  • Few challenges such as to withstand wind speed, water current speed, snow load and corrosion due to water moisture
  • Drawback : such investment is 1.2 times conventional land solar installations

A survey on floating solar power[7]

  • Explains need of floating solar system and feasibility of solar power in India with almost 300 days of sunshine
  • HDPE (High Density Poly Ethylene) with cheaper cost and reliability is proposed choice for installation
  • HDPE structure is shown with schematic diagram in the paper
  • Describes installation at Far Niente Winery in Napa California (SPG)
  • Describes installation at Kolkata commissioned by VikramSolar and Arka College

WREF 2012: P50/P90 ANALYSIS FOR SOLAR ENERGY SYSTEMS USING THE SYSTEM ADVISOR MODEL[8]

Abstract: Before installing a solar power plant the financial risk associated with has to be analyzed. There are different methodology used for this purpose and in this paper two metodology used by NREL is described.

  • Data without describing the major event for the particular location can be found from Typical Meteorological Year data sets, which are used for preliminary research
  • More detailed analysis for solar radiation and weather data are available at National Solar Radiation Database(NSRDB) and National Climatic Data Center(NCDC)
  • In 50 method the possibilities of power output greater than 50% of the preset value is 50% and silmilar in P90 method it is greater than 90%

Modeling Photovoltaic and Concentrating Solar Power Trough Performance, Cost, and Financing with the Solar Advisor Model[9]

  • Built System Advisor Model(SAM) by the staff of NREL and Sandia National Laboratory to support the professionals of solar industry doing reserch in solar
  • SAM is used to compare different solar technology on the same platform from the point of view of performance, cost and economic aspects
  • Having user friendly GUI interface so anybody can use it effectively
  • SAM has some readily available models for different pv modulesand for inverters to compare the performance

PV system model reduction for reliability assessment studies[10]

  • Analyzed the reliability of solar photovoltaic energy in modern power systems

Comparison of PV System for land and water body

Study on performance of 80 watt floating photovoltaic panel[11]

  • The efficiency reduces by 0.485% per 1 degree C increase in temperature
  • Use of PVC pipe and Al as floating structure due to their light weight and thermal conductivity respectively
  • Tilt angle needs to be between 0 to 7 degrees for Peninsular Malaysia
  • Proposed for places with one season throughout the year
  • Temperature difference for foalting and overland installation is compared
  • Energy gain difference between both types is compared showing superior performance of floating PV
  • Power gain increased by 15.5% for floating PV under this study

A Study on Power Generation Analysis of Floating PV System Considering Environmental Impact[12]

  • Performance Analysis of Hapcheon 100 and 500kW floating solar PV is presented over the months of the year
  • On the basis of average generation, floating plant is expensive than overland plant
  • Juam 2.4kW floating Vs overland PV system superior performance of floating installation
  • Effect of wind speed with change in orientation and location (due to movement) is studied for Juam floating solar PV.
  • Generating efficiency for floating installation is 11% higher than overland installations by ignoring the effects of wind.

A study of floating PV Module Efficiency

Muscat, Melanie, "A study of floating PV Module Efficiency" (2014).[13]

  • Experiments are conducted in a place (Maltese islands) with higher irradiation and the ratio of water to land area is 10:1.
  • Different setups are compared such as solar panels on land, panels on floating water and panels on sea water with salt accumulated on it.
  • Water cooled setup performed better than the non-water cooled system by a factor of 9.6% in summer and by 3% in winter.
  • Sea salt accumulated system produced 3.8% greater energy output than the ground reflected system.
  • As it is more costlier to deploy solar panels on water than on the land, the power produced per square meter of the material used is of greater importance ad it is high for crystalline cells.
  • On the whole energy efficiency is always high for a floating panel than the terrestrial one.

H2O saving simulation


Evaluating Potential for floating solar installations on Arizona Water Management[14]

  • Study highlights the need of foatovolatics and terms it as “drought adaptation technology”
  • Water loss through Central Arizona Project is around 4.4% equating to 58,921,434 gallons per day
  • Reduction of carcinogenic content in water due to lowering exposure to sunlight for bromate formation from chlorine and bromine
  • NREL estimation ignores transmission infrastructure and other costs and reliability
  • Various deigns of floating installations are discussed
  • Savings in water are evaluated using an empirical formula
  • A pilot location is proposed at lake Pleasant Reservoir
  • Cost per watt is $1.36 including the advantage of government subsidy

Evaporation Reduction by Suspended and Floating Covers: Overview, Modelling and Efficiency [15]

  • Design for Australia's South East Queensland which has heavy pressure of water demand
  • Use of suspended covers and floating covers, types of covers are discussed
  • Highest efficiency for SuperSpan covers together with greater life
  • Evaporation rate expression used for modeling the evaporation
  • Cost comparison shows cost per KL water for SuperSpan ranks second (after AquaCap)
  • 2D model is presented and 3D model is proposed for future research work

Economics of PV on water body and sensitivity analysis


Floatovoltaics: Quantifying the Benefits of a Hydro-Solar Power Fusion

McKay, Abe, "Floatovoltaics: Quantifying the Benefits of a Hydro-Solar Power Fusion" (2013). Pomona Senior Theses. Paper 74 [16]

  • Pairing of water and solar could increase production efficiency by 8-10% through panel cooling and save millions of litres of water from evaporation.
  • A Floatovoltaic system is feasible only when the benefits of the project such as water saved from cooling and reduced evaporation plus the increase in power output outweigh the floating costs.
  • Shading water with the solar arrays can reduce the evaporation losses by 70%.
  • Maximum power is linearly related to both temperature and irradiance.
  • In areas with lots of irradiance and low land prices like deserts, electricity has to be transported long distances to reach users.
  • 6% of United States electrical energy is lost during transmission and distribution.
  • Connecting a solar array to the existing power grid would save on transmission infrastructure costs.

Sustainability

Analysis of the Potential for Use of Floating Photovoltaic Systems on Mine Pit Lakes: Case Study at the Ssangyong Open-Pit Limestone Mine in Korea [17]

  • Abandoned mine sites can be utilized for implementation of solar PV
  • Limiting factors includes availability of smaller area with shading effects
  • SAM modeling performed using weather information and proposed generation along with studies on economy showing return in 12.3 years in Koeran Mine Pit Lakes
  • Annual reduction in emissions found to be 471.21tCO2/year
  • Location, temperature, wind speed, irradiance level
  • Using ArcGIS the feasible site was determined along with design of PV system (tilt angles, required area, PV module, inverter)
  • Net present value (NPV) and Greenhouse gas reduction expressions are presented.
  • Variations in output w.r.t. tilt angles
  • Although, PV system installation needs 1.7 times higher expenditure than forestation of same area, but GHG emissions are reduced by half.

Contributors


Arpit Pravin Sreenija Surya Tanmoy


References

  1. K.A. Moharram, M.S.A. Elhady, H.A. Kandil, H.E. Sherif
  2. Giuseppina Ciulla, Valerio Lo Brano, Vincenzo Franzitta, and Marco Trapanese
  3. Hashim A Hussien, Ali H Numan and Abdulmunem R Abdulmunem
  4. H. M. Bahaidarah, S. Rehman, P. Gandhidasan and B. Tanweer
  5. Sandhya S, Narciss Starbell R and Jims John Wessley G
  6. Paritosh Sharma, Bharat Muni, Debojyoti Sen
  7. N. Krishnaveni, P. Anbarasu, D. Vigneshkumar
  8. Aron P. Dobos, Michael Kasberg, Paul Gilman
  9. Nathan Blair, Mark Mehos, Craig Christensen, Craig Cameron
  10. Tokhir Gafurov, Julio Usaola
  11. Z.A.A. Majid, M.H. Ruslan, K. Sopian, M.Y. Othman and M.S.M. Azmi
  12. Young-Kwan Choi
  13. Muscat, Melanie
  14. Hartzell, Tynan Scott
  15. Xi Yao, Hong Zhang, Charles Lemckert, Adam Brook and Peter Schouten
  16. McKay, Abe.,
  17. Jinyoung Song and Yosoon Choi
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