Lecture notes/Week 5 PRAC slides.pptx RSE 3141 Solar Energy Week 5 PRAC In groups, look up some spec sheets (technical details) for solar panels currently on the market What type of cells do they use?...

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Examsubject: Solar EnergyDay: WedTime: 9:00 Melbourne time zone - AustraliaDuration: 1 hr , 40 minsDate: 16/6/2021Note: * The exam will be a set of 5 questions* Write text answers in word document* Some spreadsheet calculations will be required
* Show calculation, graphs, etc


Lecture notes/Week 5 PRAC slides.pptx RSE 3141 Solar Energy Week 5 PRAC In groups, look up some spec sheets (technical details) for solar panels currently on the market What type of cells do they use? How many cells are in a module? What is Voc, Isc, Vmax and Imax? What is the overall capacity (W) for the module What is the mass of the module/panel If we assume that if we shine 1000Wm-2 of solar radiation on the panel you will get the nameplate capacity, what is the assumed total efficiency? How does that compare with the expected efficiency based on the NREL chart: https://www.nrel.gov/pv/cell-efficiency.html How does it compare with the reported efficiency? Exercise #1: Configuration of solar panels currently on the market Need to work out the overall energy intensity of silicon (lecture notes) How much silicon (and other materials) is there in a panel? How much power does a panel produce? How many months of deployment are required to offset energy inputs? Just use approximates. Google is your friend here. Exercise #2: What is the energy payback for a PV panel? https://publications.jrc.ec.europa.eu/repository/bitstream/JRC100783/2016.3057_src_en_final_2%20(002).pdf Make up of a solar panel A typical 200 W panel weights 22kg https://en.wikipedia.org/wiki/Embodied_energy (based on https://www.circularecology.com/embodied-energy-and-carbon-footprint-database.html#.Xp4XIy-r1TY) Energy produced: Polycrystalline silicon panel: Assume 200 W panel, averaging 20% capacity factor Monocrystalline silicon panel: Assume 250 W panel, averaging 20% capacity factor Embodied energy __MACOSX/Lecture notes/._Week 5 PRAC slides.pptx Lecture notes/Week 8 Integration_2021.pptx RSE3141 Solar Energy Energy Markets, Storage and Integration Roger Dargaville ([email protected]) Resources Engineering 1 Building integrated energy systems Energy markets Generation mix Transmission Demand-side management Storage Storage Basic concepts Batteries Pumped hydro Other forms Integration Optimal mix of generation, storage and transmission assets for a low carbon future What’s coming up rest of semester Week 9: Active and passive solar design Building better buildings Week 10: Connecting to the grid Guest lecture from Reza Razzaghi (Elec Eng) Week 11: Siting solar PV projects Guest lecture from Steve Phillips Week 12: Wrap up and research lecture Overview 2 https://www.pv-magazine-australia.com/2021/03/18/south-australian-rooftop-solar-switched-off-in-search-for-stability/ Australian Energy Market Commission (AEMC) currently finalising a rule change that will see PV prevented from feeding into the grid when residual demand is very low Will allow more PV onto the grid May incentive more batteries https://www.aemc.gov.au/news-centre/media-releases/new-plan-make-room-grid-more-home-solar-and-batteries Role of PV and batteries is very topical at the moment Supply and demand must be perfectly matched all the time The market operator predicts what the demand for the next time period will be Based on time of day and year, weather, included rooftop PV (behind the meter) Generators ‘bid in’ their capacity Related to their operational expenditure The market operator directs which generators should dispatch and how much Takes into account the costs Flexibility Transmission constraints Error in the forecast and possible system faults – extra ‘spinning reserve’ How does the electrical energy market work? GW demand in Victoria for Heatwave in Jan 2014 ‘Normal’ week Base-load Intermediate Peak Coal Gas Hydro Wind Jan 2014 Extreme and mild examples https://opennem.org.au/energy/nem/?range=7d&interval=30m Demand has evolved to match the supply characteristics – cheap off peak power, deals for large continuous users, large industrial use. Potential for efficiency, load shifting to change the shape to match a different mix is there. System cannot operate with baseload alone – requirement for peaking capacity to follow large swings in demand 5 TechnologyCarbon IntensityDispatchabilityRamp ratesCost HydroLOW_MEDIUMYES*FASTMEDIUM NuclearSLOWYESSLOWHIGH CoalHIGHYESSLOWMEDIUM Gas - CCGTMEDIUMYESMEDIUMLOW-MEDIUM Gas - OCGTMEDIUM-HIGHYESFASTLOW Wind turbinesLOWNO-LOW Solar PVLOWNO-LOW Solar thermalLOWYESMEDIUMHIGH Electricity options and characteristics * Subject to drought Generator typeStart from coldStart from hotSpinning from low to high Coal - Brown24-48 hours~6 hours1-2 hours Coal - Black12-24 hours~4-6 hours1-2 hours Gas - CCGT4-6 hours1-2 hours~ 10 minutes Gas - OCGT1-2 hours1-2 minutes<1 minute hydro1-2 minutes5-30 seconds1-10 seconds start up and ramp rates specific to each generator – some may be quicker or slower depending on configuration electricity generation capacity mix in the nem nsw1 black coalbrown coalocgtgas - steamccgtdieselreciprocatinghydrobioenergywindpv10240013880620178.7153.800000000000012650.55108.211650.981563.2972119999999qld1 black coalbrown coalocgtgas - steamccgtdieselreciprocatinghydrobioenergywindpv81490164201210454173.76618327.96121789.0585779999981sa1black coalbrown coalocgtgas - steamccgtdieselreciprocatinghydrobioenergywindpv0073012806582669.92.5131473.45755.76023500000088tas1black coalbrown coalocgtgas - steamccgtdieselreciprocatinghydrobioenergywindpv001630208224022612308105.116405vic1black coalbrown coalocgtgas - steamccgtdieselreciprocatinghydrobioenergywindpv06290186450000132237.6551.1520000000000081242.40000000000011080.6378609999999https://www.aemc.gov.au/energy-system/electricity/electricity-market/spot-and-contract-markets https://www.aemc.gov.au/sites/default/files/content//five-minute-settlement-directions-paper-fact-sheet-final.pdf what is the spot market? what is the contract market? swaps caps https://www.asx.com.au/products/energy-derivatives/australian-electricity.htm how does the electricity market work (australia) how the market works spot price is determined based of the demand and the bids of the generators market ‘settles’ based on these prices market corrects based on the contract market the price the consumer pays is only partly driven by the spot market price for electricity but it also includes network costs retail mark-up green certification (renewable energy certificates) carbon costs (not at the moment) network cost (”poles and wires”) make up the biggest portion (not energy). relating the wholesale (spot market) price to the retail price trends in electricity prices (indexed to 2015) and projections https://www.aemo.com.au/-/media/files/electricity/nem/planning_and_forecasting/demand-forecasts/efi/jacobs-retail-electricity-price-history-and-projections_final-public-report-june-2017.pdf?la=en&hash=7a21136f67086a90d182a43f81bccbbe since 2007, prices have increased around 60% most of the increase occurred between 2007 and 2015 around 20-30% is generation ~15% is retailer chargers ~50% is network charges transmission system is a natural monopoly needs to be regulated regulated markets can be poorly managed overly generous – too expensive not generous enough – lack of capacity what makes up your electricity bill? http://www.ipart.nsw.gov.au/ breakdown of bills for different states in australia https://www.aemo.com.au/-/media/files/electricity/nem/planning_and_forecasting/demand-forecasts/efi/jacobs-retail-electricity-price-history-and-projections_final-public-report-june-2017.pdf?la=en&hash=7a21136f67086a90d182a43f81bccbbe contribution of different factors to decrease in demand 2009-2013 https://australiainstitute.org.au/report/power-down-ii-australias-electricity-demand/ main reason for decrease is energy efficiency light bulbs motors air conditioning/ refrigeration other important reasons are price effects lower than expected growth industrial closures (e.g. car industry, aluminium) generation trend (2005-2020) (gwh/yr) 100000 80000 60000 40000 20000 2005 2007 2009 2011 2013 2015 2017 2019 why use energy storage? what are the technologies? hydro batteries compressed air fly wheel costs? energy storage hornsdale power reserve (south australia) aka tesla big battery impact of storage on energy systems thanks to rob clinch @ arup have a look at opennem.org.au transformers transmission distribution generation sub station commercial and industrial customers residential customers storage storage storage storage storage grid stabilisation renewable storage peak load relief ups and arbitrage domestic arbitrage storage applications in the grid pumped hydro (180gw) chemical and flow batteries flywheels thermal storage systems storage technologies – global capacity https://www.sandia.gov/ess/global-energy-storage-database/ 20 [category name] [category name] compressed air energy storageelectro-chemicalelectro-mechanicalhydrogen storageliquid air energy storagelithium ion batterythermal storagepumped hydro storage8410329717826006882048553507541203275126181190506 [category name] [category name] [category name] compressed air energy storageelectro-chemicalelectro-mechanicalhydrogen storageliquid air energy storagelithium ion batterythermal storage8410329717826006882048553507541203275126 pumped hydro simple reversal of the hydro system. works with francis type turbines okinawa pumped seawater system australia currently has 3 pumped hydro systems, tumut 3 (660 mw), shoalhaven (240mw) and wivenhoe (500mw) used in conjunction with a gas fired turbine – improves efficiency by a factor of 3 pumps compress air underground when power is cheap compressed air storage 2 utility scale projects running – 290 mw huntorf plant, (germany) and 110 mw plant in mcintosh (alabama) work by storing energy in chemical bonds. lead acid invented in 1859 (planté), refined by fauré (1881) typically designed for small appliances (i.e. li-ion in laptops) or short sharp usage (i.e. car battery) more recently for transport (evs) and energy storage lots of different types lead acid lithium ion sodium/sulfur vanadium-redox flow electro-chemical batteries pb + pbo2 + 2h2so4 2pbso4 + 2h2o flywheels store energy as angular momentum best suited to storage periods of 1 second to 10 minutes the flywheel case is designed with a shield to contain a failed rotor and its pieces if it shatters and blows up batteries are much cheaper than flywheel systems (moving parts) but flywheels can charge/discharge many more times flywheels 070403 images courtesy of beacon power source: www.ecolectic.org 24 compressed h2 and ng storage hydrogen storage – well proven produce h2 by electrolysis of water (or from fossil fuel, but that’s not sustainable!) h2 pressures range from 2000 to 10,000 psi cng (compressed natural gas) is stored at 3000 psi nh4 (ammonia) another possible medium key issue is efficiency of producing hydrogen and gas compression and then efficiency of electricity production 25 thermal storage can be stored for days potential for additional storage from off the grid expensive infrastructure molten salt integrated into csp 3 main stages: liquefaction, storage, and power recovery liquid air energy storage pilot plant: highview power storage (slough, uk) 300kw – planning 10mw system now round-trip efficiency (rte) of the system: 8-12% (with 60c waste heat) but claim they can get an efficiency of 60% in the 10mw plant capital cost storage capacity and discharge times cost per discharge i.e. how much do i need to store for how long, how many times will it cycle? which storage system to choose? 29 lots of different technologies with different characteristics capacity, power, response time, cost pumped hydro most favourable for medium response speed storage, but needs appropriate hydrology and geography. caes also has geological constraints battery technologies evolving as incentives improve (i.e. higher penetration of re leading to more variability in energy systems) storage summary demand-side management can alter demand patterns shape load new users for off-peak shift load off-peak hot water reduce load efficiencies increase load electric vehicles http://siteresources.worldbank.org/intenergy/resources/primerondemand-sidemanagement.pdf what will the electrical energy system of the future look like?depends on: the target we aim to hit (50, 80 or 100% emission abatement?) cost of technologies resource availability role of storage and demand side management where, when and how much of what technologies should be built? assumes a centrally run, well coordinated energy system… least cost system modelling demand has evolved to match the supply characteristics – cheap off peak power, deals for large continuous users, large industrial use. potential for efficiency, load shifting to change the shape to match a different mix is there. system cannot operate with baseload alone – requirement for peaking capacity to follow large swings in demand 35 broad range of technologies available conventional technologies coal, gas, nuclear – reliable, but come with emissions + risk established renewables wind, solar pv, hydro – low carbon but intermittent/constrained emerging renewables concentrating solar thermal, wave, geothermal, biomass, biogas – expensive storage – phes and distributed batteries plus need to worry about transmission, security of supply, voltage and frequency stability things to consider build a simulation tool of the nem of medium complexity run an optimisation routine to find the least cost combination for a given emission reduction target. model considers hourly variability, discount rate (10%) and other scenarios (low discount, higher non-synchronous allowances…) considers the transition (not just a snap shot in 2050) approach modelling setup find the least cost total system cost for a combination of generation technologies for 100% emission abatement by 2050 (other targets also possible) broad range of technologies considered (technology agnostic) coal (brown and black coal), gas (ocgt and ccgt) hydro, wind, solar concentrating solar thermal, carbon capture and storage (ccs), bioenergy, pumped hydro energy storage (phes) at same time consider transmission constraints and costs of additional transmission capacity hourly economic dispatch model, inertia constraints, ramp rates, unit commitment we run 8 hours of storage for both phes and csp discount rate: 10% electrification of transport 1.4 times minute="" hydro="" 1-2="" minutes="" 5-30="" seconds="" 1-10="" seconds="" start="" up="" and="" ramp="" rates="" specific="" to="" each="" generator="" –="" some="" may="" be="" quicker="" or="" slower="" depending="" on="" configuration="" electricity="" generation="" capacity="" mix="" in="" the="" nem="" nsw1="" black="" coal="" brown="" coal="" ocgt="" gas="" -="" steam="" ccgt="" diesel="" reciprocating="" hydro="" bioenergy="" wind="" pv="" 10240="" 0="" 1388="" 0="" 620="" 178.7="" 153.80000000000001="" 2650.55="" 108.211="" 650.98="" 1563.2972119999999="" qld1="" black="" coal="" brown="" coal="" ocgt="" gas="" -="" steam="" ccgt="" diesel="" reciprocating="" hydro="" bioenergy="" wind="" pv="" 8149="" 0="" 1642="" 0="" 1210="" 454="" 173.76="" 618="" 327.96="" 12="" 1789.0585779999981="" sa1="" black="" coal="" brown="" coal="" ocgt="" gas="" -="" steam="" ccgt="" diesel="" reciprocating="" hydro="" bioenergy="" wind="" pv="" 0="" 0="" 730="" 1280="" 658="" 266="" 9.9="" 2.5="" 13="" 1473.45="" 755.76023500000088="" tas1="" black="" coal="" brown="" coal="" ocgt="" gas="" -="" steam="" ccgt="" diesel="" reciprocating="" hydro="" bioenergy="" wind="" pv="" 0="" 0="" 163="" 0="" 208="" 224="" 0="" 2261="" 2="" 308="" 105.116405="" vic1="" black="" coal="" brown="" coal="" ocgt="" gas="" -="" steam="" ccgt="" diesel="" reciprocating="" hydro="" bioenergy="" wind="" pv="" 0="" 6290="" 1864="" 500="" 0="" 0="" 13="" 2237.65="" 51.152000000000008="" 1242.4000000000001="" 1080.6378609999999="" https://www.aemc.gov.au/energy-system/electricity/electricity-market/spot-and-contract-markets="" https://www.aemc.gov.au/sites/default/files/content//five-minute-settlement-directions-paper-fact-sheet-final.pdf="" what="" is="" the="" spot="" market?="" what="" is="" the="" contract="" market?="" swaps="" caps="" https://www.asx.com.au/products/energy-derivatives/australian-electricity.htm="" how="" does="" the="" electricity="" market="" work="" (australia)="" how="" the="" market="" works="" spot="" price="" is="" determined="" based="" of="" the="" demand="" and="" the="" bids="" of="" the="" generators="" market="" ‘settles’="" based="" on="" these="" prices="" market="" corrects="" based="" on="" the="" contract="" market="" the="" price="" the="" consumer="" pays="" is="" only="" partly="" driven="" by="" the="" spot="" market="" price="" for="" electricity="" but="" it="" also="" includes="" network="" costs="" retail="" mark-up="" green="" certification="" (renewable="" energy="" certificates)="" carbon="" costs="" (not="" at="" the="" moment)="" network="" cost="" (”poles="" and="" wires”)="" make="" up="" the="" biggest="" portion="" (not="" energy).="" relating="" the="" wholesale="" (spot="" market)="" price="" to="" the="" retail="" price="" trends="" in="" electricity="" prices="" (indexed="" to="" 2015)="" and="" projections="" https://www.aemo.com.au/-/media/files/electricity/nem/planning_and_forecasting/demand-forecasts/efi/jacobs-retail-electricity-price-history-and-projections_final-public-report-june-2017.pdf?la="en&hash=7A21136F67086A90D182A43F81BCCBBE" since="" 2007,="" prices="" have="" increased="" around="" 60%="" most="" of="" the="" increase="" occurred="" between="" 2007="" and="" 2015="" around="" 20-30%="" is="" generation="" ~15%="" is="" retailer="" chargers="" ~50%="" is="" network="" charges="" transmission="" system="" is="" a="" natural="" monopoly="" needs="" to="" be="" regulated="" regulated="" markets="" can="" be="" poorly="" managed="" overly="" generous="" –="" too="" expensive="" not="" generous="" enough="" –="" lack="" of="" capacity="" what="" makes="" up="" your="" electricity="" bill?="" http://www.ipart.nsw.gov.au/="" breakdown="" of="" bills="" for="" different="" states="" in="" australia="" https://www.aemo.com.au/-/media/files/electricity/nem/planning_and_forecasting/demand-forecasts/efi/jacobs-retail-electricity-price-history-and-projections_final-public-report-june-2017.pdf?la="en&hash=7A21136F67086A90D182A43F81BCCBBE" contribution="" of="" different="" factors="" to="" decrease="" in="" demand="" 2009-2013="" https://australiainstitute.org.au/report/power-down-ii-australias-electricity-demand/="" main="" reason="" for="" decrease="" is="" energy="" efficiency="" light="" bulbs="" motors="" air="" conditioning/="" refrigeration="" other="" important="" reasons="" are="" price="" effects="" lower="" than="" expected="" growth="" industrial="" closures="" (e.g.="" car="" industry,="" aluminium)="" generation="" trend="" (2005-2020)="" (gwh/yr)="" 100000="" 80000="" 60000="" 40000="" 20000="" 2005="" 2007="" 2009="" 2011="" 2013="" 2015="" 2017="" 2019="" why="" use="" energy="" storage?="" what="" are="" the="" technologies?="" hydro="" batteries="" compressed="" air="" fly="" wheel="" costs?="" energy="" storage="" hornsdale="" power="" reserve="" (south="" australia)="" aka="" tesla="" big="" battery="" impact="" of="" storage="" on="" energy="" systems="" thanks="" to="" rob="" clinch="" @="" arup="" have="" a="" look="" at="" opennem.org.au="" transformers="" transmission="" distribution="" generation="" sub="" station="" commercial="" and="" industrial="" customers="" residential="" customers="" storage="" storage="" storage="" storage="" storage="" grid="" stabilisation="" renewable="" storage="" peak="" load="" relief="" ups="" and="" arbitrage="" domestic="" arbitrage="" storage="" applications="" in="" the="" grid="" pumped="" hydro="" (180gw)="" chemical="" and="" flow="" batteries="" flywheels="" thermal="" storage="" systems="" storage="" technologies="" –="" global="" capacity="" https://www.sandia.gov/ess/global-energy-storage-database/="" 20="" [category="" name]="" [category="" name]="" compressed="" air="" energy="" storage="" electro-chemical="" electro-mechanical="" hydrogen="" storage="" liquid="" air="" energy="" storage="" lithium="" ion="" battery="" thermal="" storage="" pumped="" hydro="" storage="" 8410="" 3297178="" 2600688="" 20485="" 5350="" 754120="" 3275126="" 181190506="" [category="" name]="" [category="" name]="" [category="" name]="" compressed="" air="" energy="" storage="" electro-chemical="" electro-mechanical="" hydrogen="" storage="" liquid="" air="" energy="" storage="" lithium="" ion="" battery="" thermal="" storage="" 8410="" 3297178="" 2600688="" 20485="" 5350="" 754120="" 3275126="" pumped="" hydro="" simple="" reversal="" of="" the="" hydro="" system.="" works="" with="" francis="" type="" turbines="" okinawa="" pumped="" seawater="" system="" australia="" currently="" has="" 3="" pumped="" hydro="" systems,="" tumut="" 3="" (660="" mw),="" shoalhaven="" (240mw)="" and="" wivenhoe="" (500mw)="" used="" in="" conjunction="" with="" a="" gas="" fired="" turbine="" –="" improves="" efficiency="" by="" a="" factor="" of="" 3="" pumps="" compress="" air="" underground="" when="" power="" is="" cheap="" compressed="" air="" storage="" 2="" utility="" scale="" projects="" running="" –="" 290="" mw="" huntorf="" plant,="" (germany)="" and="" 110="" mw="" plant="" in="" mcintosh="" (alabama)="" work="" by="" storing="" energy="" in="" chemical="" bonds.="" lead="" acid="" invented="" in="" 1859="" (planté),="" refined="" by="" fauré="" (1881)="" typically="" designed="" for="" small="" appliances="" (i.e.="" li-ion="" in="" laptops)="" or="" short="" sharp="" usage="" (i.e.="" car="" battery)="" more="" recently="" for="" transport="" (evs)="" and="" energy="" storage="" lots="" of="" different="" types="" lead="" acid="" lithium="" ion="" sodium/sulfur="" vanadium-redox="" flow="" electro-chemical="" batteries="" pb="" +="" pbo2="" +="" 2h2so4="" 2pbso4="" +="" 2h2o="" flywheels="" store="" energy="" as="" angular="" momentum="" best="" suited="" to="" storage="" periods="" of="" 1="" second="" to="" 10="" minutes="" the="" flywheel="" case="" is="" designed="" with="" a="" shield="" to="" contain="" a="" failed="" rotor="" and="" its="" pieces="" if="" it="" shatters="" and="" blows="" up="" batteries="" are="" much="" cheaper="" than="" flywheel="" systems="" (moving="" parts)="" but="" flywheels="" can="" charge/discharge="" many="" more="" times="" flywheels="" 070403="" images="" courtesy="" of="" beacon="" power="" source:="" www.ecolectic.org="" 24="" compressed="" h2="" and="" ng="" storage="" hydrogen="" storage="" –="" well="" proven="" produce="" h2="" by="" electrolysis="" of="" water="" (or="" from="" fossil="" fuel,="" but="" that’s="" not="" sustainable!)="" h2="" pressures="" range="" from="" 2000="" to="" 10,000="" psi="" cng="" (compressed="" natural="" gas)="" is="" stored="" at="" 3000="" psi="" nh4="" (ammonia)="" another="" possible="" medium="" key="" issue="" is="" efficiency="" of="" producing="" hydrogen="" and="" gas="" compression="" and="" then="" efficiency="" of="" electricity="" production="" 25="" thermal="" storage="" can="" be="" stored="" for="" days="" potential="" for="" additional="" storage="" from="" off="" the="" grid="" expensive="" infrastructure="" molten="" salt="" integrated="" into="" csp="" 3="" main="" stages:="" liquefaction,="" storage,="" and="" power="" recovery="" liquid="" air="" energy="" storage="" pilot="" plant:="" highview="" power="" storage="" (slough,="" uk)="" 300kw="" –="" planning="" 10mw="" system="" now="" round-trip="" efficiency="" (rte)="" of="" the="" system:="" 8-12%="" (with="" 60c="" waste="" heat)="" but="" claim="" they="" can="" get="" an="" efficiency="" of="" 60%="" in="" the="" 10mw="" plant="" capital="" cost="" storage="" capacity="" and="" discharge="" times="" cost="" per="" discharge="" i.e.="" how="" much="" do="" i="" need="" to="" store="" for="" how="" long,="" how="" many="" times="" will="" it="" cycle?="" which="" storage="" system="" to="" choose?="" 29="" lots="" of="" different="" technologies="" with="" different="" characteristics="" capacity,="" power,="" response="" time,="" cost="" pumped="" hydro="" most="" favourable="" for="" medium="" response="" speed="" storage,="" but="" needs="" appropriate="" hydrology="" and="" geography.="" caes="" also="" has="" geological="" constraints="" battery="" technologies="" evolving="" as="" incentives="" improve="" (i.e.="" higher="" penetration="" of="" re="" leading="" to="" more="" variability="" in="" energy="" systems)="" storage="" summary="" demand-side="" management="" can="" alter="" demand="" patterns="" shape="" load="" new="" users="" for="" off-peak="" shift="" load="" off-peak="" hot="" water="" reduce="" load="" efficiencies="" increase="" load="" electric="" vehicles="" http://siteresources.worldbank.org/intenergy/resources/primerondemand-sidemanagement.pdf="" what="" will="" the="" electrical="" energy="" system="" of="" the="" future="" look="" like?="" depends="" on:="" the="" target="" we="" aim="" to="" hit="" (50,="" 80="" or="" 100%="" emission="" abatement?)="" cost="" of="" technologies="" resource="" availability="" role="" of="" storage="" and="" demand="" side="" management="" where,="" when="" and="" how="" much="" of="" what="" technologies="" should="" be="" built?="" assumes="" a="" centrally="" run,="" well="" coordinated="" energy="" system…="" least="" cost="" system="" modelling="" demand="" has="" evolved="" to="" match="" the="" supply="" characteristics="" –="" cheap="" off="" peak="" power,="" deals="" for="" large="" continuous="" users,="" large="" industrial="" use.="" potential="" for="" efficiency,="" load="" shifting="" to="" change="" the="" shape="" to="" match="" a="" different="" mix="" is="" there.="" system="" cannot="" operate="" with="" baseload="" alone="" –="" requirement="" for="" peaking="" capacity="" to="" follow="" large="" swings="" in="" demand="" 35="" broad="" range="" of="" technologies="" available="" conventional="" technologies="" coal,="" gas,="" nuclear="" –="" reliable,="" but="" come="" with="" emissions="" +="" risk="" established="" renewables="" wind,="" solar="" pv,="" hydro="" –="" low="" carbon="" but="" intermittent/constrained="" emerging="" renewables="" concentrating="" solar="" thermal,="" wave,="" geothermal,="" biomass,="" biogas="" –="" expensive="" storage="" –="" phes="" and="" distributed="" batteries="" plus="" need="" to="" worry="" about="" transmission,="" security="" of="" supply,="" voltage="" and="" frequency="" stability="" things="" to="" consider="" build="" a="" simulation="" tool="" of="" the="" nem="" of="" medium="" complexity="" run="" an="" optimisation="" routine="" to="" find="" the="" least="" cost="" combination="" for="" a="" given="" emission="" reduction="" target.="" model="" considers="" hourly="" variability,="" discount="" rate="" (10%)="" and="" other="" scenarios="" (low="" discount,="" higher="" non-synchronous="" allowances…)="" considers="" the="" transition="" (not="" just="" a="" snap="" shot="" in="" 2050)="" approach="" modelling="" setup="" find="" the="" least="" cost="" total="" system="" cost="" for="" a="" combination="" of="" generation="" technologies="" for="" 100%="" emission="" abatement="" by="" 2050="" (other="" targets="" also="" possible)="" broad="" range="" of="" technologies="" considered="" (technology="" agnostic)="" coal="" (brown="" and="" black="" coal),="" gas="" (ocgt="" and="" ccgt)="" hydro,="" wind,="" solar="" concentrating="" solar="" thermal,="" carbon="" capture="" and="" storage="" (ccs),="" bioenergy,="" pumped="" hydro="" energy="" storage="" (phes)="" at="" same="" time="" consider="" transmission="" constraints="" and="" costs="" of="" additional="" transmission="" capacity="" hourly="" economic="" dispatch="" model,="" inertia="" constraints,="" ramp="" rates,="" unit="" commitment="" we="" run="" 8="" hours="" of="" storage="" for="" both="" phes="" and="" csp="" discount="" rate:="" 10%="" electrification="" of="" transport="" 1.4="">
Answered 15 days AfterJun 03, 2021RSE3141Monash University

Answer To: Lecture notes/Week 5 PRAC slides.pptx RSE 3141 Solar Energy Week 5 PRAC In groups, look up some spec...

Swapnil answered on Jun 16 2021
159 Votes
1
    From BP Statistical Review of World Energy, the four biggest consumers of electricity in 2019 are
· Canada
· Mexico
· United States
Their per capita consumption in MWh
· Canada = 27777.77 MWh
· Mexico = 5677.91 MWh
· US = 2056.60 MWh
· The first was US country which was installed most PV in the 2006.
· The US country was installed the most in the 2011.
· 2014
was the first year that was the country to add the newest PV globally.
· An Australia get the 18th rank globally in the terms of new PV installed in 2019.
    2
    The following graph shows us the different components of the solar radiation. So the graph can be depicted to the different timing for the various temperature as shown in the below.
So now we can work on the Bird model that can give us the solar radiation that is already used with the different weather panel in the Brisbane for January 1 and July 1 for the panels of the 30 degrees’ tilt and for the panel orientation of 90 (east facing), 0 (North facing) and -90 (West facing).
The panels can have the different direction faces and it can give the following pros and cons.
First we need to know the solar panel pros and cons, so the solar panel can generate the electricity that can take the help of the sun light and the solar energy from the sun.
· The solar panel basically used for the large numbers by the resident owners to reducing the monthly electricity bills, so there are the different lot of things that we need to considering the solar energy to the part of the green leaving plan.
· The solar energy can be the sustainable alternatives to the fossil fuels and the sustainable energy sources.
· The solar energy can give the main reason to the occurring the solar panels that can be assembled to the different gadgets into the industrial facilities.
The main problem arises here that the solar energy technology can be use the generated energy while the sun is shining and in the nighttime and the overcast for the interruption can be happened into it. So the utilization of the solar energy can be creating the power that can be allowed to the free limitations to the fuels. So they can be basically required to the few meters of the residential space for the required cleaning and it can happen few times in the year.
    3A
    The basic component of the solar cell can be pure silicon which can be used for an electrical component.
· The pure silicon is the poor conductor electricity that can be used for the semiconductor material and its core component.
· In order to the overcome this problem the solar cell can be imputed to the other items and that are popularity mixed up to the silicon atom in order to the proves to the silicon ability and that can capture the suns energy and that can connect to an electricity.
· The mono crystalline solar cells can be made up of the pure type of the silicon that can make an efficient.
· Silicon is having the special popularities especially in its crystalline form.
· The combination of electrons can deflect the p-region holes and an electron can be near the junction of n-region.
· And it can carry finally p type material into changing the repetition.
P-n junctions:
· P-N junction basically formed to the joining the n-type and the p-type for the semiconductor device.
· So the n-type region has to the high electron and the p-type to the high hole concentration, and the electrons can be diffused to the n-type side and the p-type side.
· The holes can be flows by the diffusion from the p-type side and the n-type side.
However, in the p-n junction, when the electrons and the holes that can move the other side of the junction and that can leave behind the exposed charges on an atom sites, which can be fixed to the crystal line and it...
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