solarbe文库
首页 solarbe文库 > 资源分类 > PDF文档下载

Oct 2019 Conference C Case Oxford PV FINAL PDF Distribution

  • 资源大小:3.32MB        全文页数:35页
  • 资源格式: PDF        下载权限:游客/注册会员/VIP会员    下载费用:5金币 【人民币5元】
游客快捷下载 游客一键下载
会员登录下载
下载资源需要5金币 【人民币5元】

邮箱/手机:
温馨提示:
支付成功后,系统会根据您填写的邮箱或者手机号作为您下次登录的用户名和密码(如填写的是手机,那登陆用户名和密码就是手机号),方便下次登录下载和查询订单;
特别说明:
请自助下载,系统不会自动发送文件的哦;
支付方式: 微信支付    支付宝   
验证码:   换一换

 
友情提示
2、本站资源不支持迅雷下载,请使用浏览器直接下载(不支持QQ浏览器)
3、本站资源下载后的文档和图纸-无水印,预览文档经过压缩,下载后原文更清晰   
4、下载无积分?请看这里!
积分获取规则:
1充值vip,全站共享文档免费下;直达》》
2注册即送10积分;直达》》
3上传文档通过审核获取5积分,用户下载获取积分总额;直达》》
4邀请好友访问随机获取1-3积分;直达》》
5邀请好友注册随机获取3-5积分;直达》》
6每日打卡赠送1-10积分。直达》》

Oct 2019 Conference C Case Oxford PV FINAL PDF Distribution

Perovskite Production Panels Perovskite Technology for Mass Production 24 – 25 October 2019 Hangzhou, CN Dr Christopher Case Chief Technology Officer Solar PV costs drop by 200x Source BNEF – Economics of PV Power 100 10 1 0.1 1 100 10,000 1,000,00 1976 100 / watt 0.5 / wattWhy does efficiency matter17 3 Balance of system Module Balance of system 50 Module 33 Cell 17 Increase cell efficiency by 20 Overall saving Reduce cell cost by 20 Why does efficiency matter 20 of total installed cost coming from PV cellCrystalline silicon technology roadmap p‐type n‐type PERC AI‐BSF Passivated contacts Heterojunction Tandem cell heterojunction perovskite Step change in technology 19 22 23 25 30 Practical silicon limit Nearing the SQ limit – silicon flatlinesMore junctions more power, but still a fundamental limit 31 single junction SQ limit BB, 43 for two, 50 for three Multijunction SQ limit Incoming spectral power density Martin et al. Solar Energy Materials and Solar Cells 43p. 203 1996 One sun Maximum concentration One sun limit 100 80 60 40 20 0 2 4 6 8 10 Number of junctions or absorption processes Detailed balance efficiency Efficiency limit higher in multijunctionPerovskite-silicon tandem PV cells Oxford PV’s perovskite-silicon tandem solution Technology disruption without business disruption Energy converted by silicon cell Wavelength Silicon cell Energy Wavelength Silicon layer Perovskite layer Energy Tandem cell Efficiency 30 possible Silicon cell Efficiency limited to 25 Additional energy converted by perovskite cellPerovskites in tandem solar cells 2 terminal vs 4 terminal Monolithic 2-Terminal Mechanical stack 4-Terminal Optical beam splitting reflective Tandem cell architecture – 2 terminal Commercial deposition tools Contact grid Ag paste Front electrode ITO Buffer n or p-type layer p or n-type layer Metallic back electrode top cell bottom cell Si wafer Transparent interlayer Edge deletion Perovskite absorber PbI 2 basedSHJ and TOPCon structures and simplified process flow SiO x n-poly Si SiN x p-doped Si Al 2 O 3 SiN x Si n-type wafer cut Damage removal and texture PECVD i a-Si PECVD n/p a-Si PECVD p/n a-Si TCO deposition Metallisation print and cure wafer cut Damage removal and texture p-doping Single side polish Oxidation LPCVD n poly-Si Al 2 O 3 passivation front SiNxH deposition Metallisation print and fire Facile tandem integration due to full area electrically conductive front surface Highest V oc potential 740 mV of c-Si technologies and lowest TCE Tandem integration difficult due to SiNx layer Very high V oc potential 720 mV, but removal of atomic H source SiNx layer decreases carrier lifetimes leading to significant V oc reductionPredicting monolithic tandem efficiency Take best-in-class sub-cells, combine diode equations and simple TMM optics TMM optics m, R S ,R SH , EQE EL AM1.5 Optical constants Tandem PCE Hoerantner et al Energy Environ. Sci., 2017,10, 1983-1993 Perovskite-silicon 2T tandem efficiency prediction 20 PVSK 23 SI 33. with 20.5 mAcm ‐2 matching reach 33 Hoerantner et al Energy Environ. Sci., 2017,10, 1983-1993 Progress - 28 certified 1 cm 2 monolithic tandem December 2018 - IEC reliability tests passed 40 mA/cm 2Its all about reliability Light soak 60 o C RD and full size cells passed all key IEC industry wafer level accelerated tests Damp heat 85 o C/85 Rh Hours 2016 2017 2018 RD cell passed 765kWh/m 2 300-800nm Full size cell passed UV16kWh/m 2 280-400nm RD cell passed 1000 hours RD passed 2000 hours Full size cell passed 1000 hours Full size cell passed 2000 hours RD passed 3000 hours Key industry tests Thermal cycles -40 o C to 85 o C, 200 cycles RD cell passed Full size cell passedScaling the technologyJourney to perovskite solar cell technology From Professor Henry Snaith’s Oxford University lab 2010 Oxford PV established 2012 Professor Snaith’s perovskite paper 2014 Perovskite-silicon tandem solar cell development 2015 First perovskite- silicon tandem solar cell 2016 Thin film pilot line facility acquired Major industry partner Strategic investment 2017 First industry sized perovskite-silicon tandem cell produced European funding 2018 Record breaking cell New research and development campus 2019 First 60 cell full size perovskite-silicon modules fabricatedOxford PV RD center - UKOxford PV industrial site – Germany 17,000m 2Oxford PV’s perovskite-on-silicon tandem solar cell Horizontal processing Enables full area coverage – 3000 to 5000 wafers per hourLeading investors 110 million raised to date 0.7 M raised 2011 Seed round 65 per share post-money valuation 1.65 M 2013 ‘A’ round 115 per share post-money valuation 9.2 M 2015 ‘B’ round 2 closes 250/280 per share post-money valuation 39 M 2016 ‘C’ round 2 closes 300/325 per share post-money valuation 65 M 2019 ‘D’ round 2 closes EIB funding None drawn to date 5.2 M raised 12.6 M raised 16.8 M raised 65 M raised 13 M loan facility 10 M raised 2018 convertible loan250 MW manufacturing – raise it, spend it Timeline for commercialisation - 2020 2020 Pilot line 2019 / 2020 2019 Scale up Silicon cells initial volumes 250 MW manufacturing Tandem cells initial volumes PV manufacturing factory block diagram RD Engineering Fab design and expansion Incoming wafer inspection Cell workshop Module workshop Warehouse Marketing Planning Product management Sales Supply chain Facilities, water, gases, chemicals, waste treatment Quality, reliability, material analysis Logistics Cost calculation and control First 100 MW HJT line ordered Meyer BurgerProduction Costs and LCOEPerovskite-silicon tandem modules Predicted cost of 60 cell 380W tandem modules Cost model assumptions 1 GW mass production plant located in Europe 380 W tandem modules Tandem cell efficiency 27 Module efficiency 23 Annual cost € / cell € / Wp Percentage Capex 7yr depreciation € 22,420,552 € 0.12 € 0.02 6 OpEx € 338,980,766 € 1.89 € 0.30 94 Utilities € 5,240,670 € 0.03 € 0.00 2 Materials Consumables € 116,750,956 € 0.65 € 0.10 32 Labour € 21,414,500 € 0.12 € 0.02 6 Bottom cell cost € 194,998,352 € 1.09 € 0.17 54 Floor space € 354,492 € 0.00 € 0.00 0 Waste disposal € 221,796 € 0.00 € 0.00 0 Total Cost of Ownership € 361,401,318 € 2.01 € 0.32 100It is all about LCOE Low High Efficiency LCOE Low High Multi BSF Mono BSF Mono BSF PERC bifacial Passivated Contact Heterojunction Perovskite tandem Energy Yield Model Predictions EY greater for tandem than for silicon only De-rating factor from power to EY is similar to silicon “For a given power rating How much more or less energy does a tandem cell yield compared to standard si-cell” Advantage Blue response Disadvantage Spectral mismatch First model predictions at cell level show derating similar to silicon Hoerantner et al Energy Environ. Sci., 2017,10, 1983-1993 Energy yield modeling approach Example June 28 th of a typical meteorological year in Phoenix, Arizona 0 0.2 0.4 0.6 0.8 1 1.2 000 600 1200 1800 000 Normalized Jsc Top cell Bottom cell Lehr et al Energy yield modelling of perovskite/silicon two- terminal tandem PV modules with flat and textured interfaces submitted0 5 10 15 20 25 30 35 40 45 2018 2019 2020 2021 2022 2023 2024 2025 LCOE USD per MWh Perovskite tandem market penetration 20 MW scale 100 MW scale 1 GW scale Transforming solar economics Source GTM Research, ITRPV 9th Edition, Oxford PV Perovskite tandem LCOE Silicon LCOEAccelerating the adoption of solar Global electricity demand Accelerating the adoption of solar 2000 2010 2020 2030 2040 0 100 50 Silicon Primary energy use Perovskite tandem Oxford PV accelerating solar adoption 2050The future is all-electric www.oxfordpv.com chris.caseoxfordpv.com

注意事项

本文(Oct 2019 Conference C Case Oxford PV FINAL PDF Distribution)为本站会员(光伏小萝莉)主动上传,solarbe文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知solarbe文库(发送邮件至401608886@qq.com或直接QQ联系客服),我们立即给予删除!

温馨提示:如果因为网速或其他原因下载失败请重新下载,重复下载不扣分。

copyright@ 2008-2013 solarbe文库网站版权所有
经营许可证编号:京ICP备10028102号-1

1
收起
展开