DOCSLIB.ORG

Hybrid Off-Grid Solar Solution for Telecom Applications Table of Contents

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Hybrid Off-Grid Solar Solution for Telecom Applications Table of Contents Hybrid Off-Grid Solar Solution For Telecom Applications Table of Contents We Are Vertiv™....................................................................................3 Introduction to Off-Grid Solar Hybrid Off-Grid Solar Solution for Telecom ................................................4 Dedicated Services for Off-Grid Telecom Sites ...........................................6 Monitoring System .............................................................................. 7 Off-Grid Solar Solution Offering Vertiv's Off-Grid Solar Solution ...............................................................8 Netsure™ 531 Series ............................................................................ 11 NetSure™ 7100 Series ..........................................................................13 HSS 48 Series Solar Subrack Power System .............................................15 EPC48300/2900 Series Outdoor Enclosures .............................................17 Solar Panels For Telecom .....................................................................19 Solar Array Frames For Telecom ............................................................21 Solar Array Junction Box ..................................................................... 23 NCU - Netsure™ Controller ................................................................... 25 Learn More About Hybrid Solutions ....................................................... 27 2 We Are Vertiv™ Vertiv (NYSE: VRT) brings together hardware, software, analytics and ongoing services to ensure its customers’ vital applications run continuously, perform optimally and grow with their business needs. As Architects of Continuity™, Vertiv solves the most important challenges facing today’s data centers, communication networks and commercial and industrial facilities with a portfolio of power, cooling and IT infrastructure solutions and services that extends from the cloud to the edge of the network. Headquartered in Columbus, Ohio, USA, Vertiv employs approximately 20,000 people and does business in more than 130 countries. For more information, and for the latest news and content from Vertiv, visit Vertiv.com. Vertiv Services and Software Architects of Continuity™ Solutions With a unique combination of industry expertise, technology, and resources, our mission is to support and power mission- Large Infrastructure IT and Edge Infrastructure critical technologies that AC Power, DC Power, Energy Edge Systems, IT Systems, Rack, Storage, Industrial Solutions, Rack PDU, Rack Thermal, drive possibility. Thermal Rack UPS Chloride® Liebert® Netsure™ Our global industrial power solutions Our global power and thermal Our global intelligently engineered DC meet the most demanding technical management solutions are some of the power systems deliver high availability, specifications and provide safe, reliable world’s most efficient and reliable power energy efficiency and scalability for power- no matter the challenge and cooling technologies converged networks 3 Hybrid Off-Grid Solar Solution for Telecom Hybrid Off-Grid Solar Solution for Telecom With the demand for network access y Flexible to meet today's and Tailored Support for Off-Grid and mobile broadband consistently tomorrow's needs; Telecom Installations growing, the telecom sector is now experiencing an increasing need to y Reliable, resulting in improved uptime In this hyper-connected, technology improve networks and expand services and lower maintenance costs; dependent world, you can’t afford for your critical network infrastructure to go while maximising efficiency, reducing y Holistic with power protection, down. The success of your business costs and ensuring reliable performance. monitoring to service; depends on it. Our team of experts To serve this growing demand for y Cost effective, to contribute to the brings together global reach with local connectivity, telecom providers are now knowledge to take on your most expanding, more than ever, in remote short, medium and long term energy saving objectives; complex challenges, creating solutions regions, where the grid is absent. that keep your Hybrid Off-Grid Solar y Increased intelligence with 24x7 Solution running—and your business Stay on Top of Telecom Trends remote and on-site monitoring, moving. providing real-time visibility and In this environment, where conventional immediate detection of anomalies; energy sources are becoming more expensive, there is a growing y Enhanced support with a dedicated opportunity to make use of renewable team of experts to assist. energy. The solution is a hybrid 1 approach that minimises the use of Centralised Monitoring and Control diesel generators, used only in case of emergency, while maximizes the use of Minimises Operational Cost solar power and batteries, boosting the Meeting the expectations for constant performance stability and financial availability while minimizing operational return required to operate a telecom cost is key. Once your hybrid solution is business. up and running, a constant monitoring and control system provides real-time Flexible Hybrid Solutions to visibility into your remote network by Reduce OPEX and Ensure Optimal managing, controlling and validating the delivery of power from generator, solar Performance and battery to the load. All giving you Technologies that minimise expensive unparalleled system protection and energy consumption and enable flexible, support, for complete peace of mind. reliable and responsive infrastructure have been developed in recent years and will continue to evolve. 2 This critical infrastructure can now be enabled through the use of intelligent energy solutions that allow the system to adapt as conditions change. 5 3 Off-grid hybrid solutions provide 4 significant energy savings opportunities to the telecom infrastructure through: y Simplicity in design and enhanced intelligent features; 4 Challenges Consequences Opportunities Fuel expense is high due to: y Frequent generator operation y Strategically blend power from batteries, solar and other sources to achieve lowest possible energy cost y Theft and quality/dilution High operating cost y Actively manage sites to ensure proper battery health, optimal generator maintenance, clean y Site accessibility solar panels, and tracked fuel quality and level Deployment speed slowed by: y Infrastructure not in place y Ensure site readiness by selecting a single coordinator for all site infrastructure and installation y Complex supply chains Consumers choose competing carriers y Managed integrated supply chain with a common y Availability of installation experts objective for schedule and delivery Operation and maintenance costs impacted by: y Engineer the hybrid site solution for the desired y Improper hybrid dimensioning balance between capital and operational cost y Lack of site visibility post installation Increase maintenance staff y Leverage smart hybrid technologies to minimize y Calendar-based maintenance dispatch maintenance dispatch and achieve maximum ROI, even as operating conditions change Site reliability impacted by: 1 y Validate vendor focus on the technologies and skills y Use of consumer system or parts not Increase downtime and increase maintenance cost associated with deploying operating energy and designed for unattended operation passive infrastructure. y Integration of discrete parts not y Keep vendor engaged in site performance post Use of unplanned funds to keep site operational validated to work as one solution deployment 2 5 3 4 5 Hybrid Off-Grid Solar Solution for Telecom Dedicated Services for Off-Grid Telecom Sites No two situations are alike. Vertiv When evaluating a hybrid solar To maximise the potential of your supports its customers with an installation, you should look for a installation, our Telecom Professionals extensive service offering, enhancing solution that offers the most will also provide you and your staff with network availability and ensuring total comprehensive support options and a On-Site Training services, which peace of mind 24/7. With the broadest, partner that can walk you through the include installation, operation and most comprehensive service presence in design and testing as well as offer maintenance of the solution, to help you the industry and more than 600 support and training even once the understand the full power of your hybrid Customer Engineers dedicated to equipment is installed. solar station. And with the addition of a servicing Asia Pacific, Vertiv ensures dedicated Help Desk, you can always that your business is protected 100% of get direct access by phone to our the time and that assistance is close by experienced support team 24/7. whenever needed. PROJECT MAINTENANCE When launching new facilities or powering up Services to ensure that your business new equipment you want to do it the right way critical infrastructure operates reliably, – right from the start safely, and efficiently Plan Preventive and corrective Design maintenance Integrate Remote services and Commission monitoring Project Management Fan/Battery replacements Repair Spare parts Increase mean time Decrease between failure PERFORMANCE operating cost Full range of services designed to optimize infrastructure performance and reduce process complexity Assess and Configure Help Desk Audit Train Remote 6 Take Control of Your Network. Benefits Monitoring System y Improved availability As your network expands, the demand Via remote connection, the supervisory • Minimize downtime to get
Load more

Recommended publications
  • Commercialization and Deployment at NREL: Advancing Renewable
    Commercialization and Deployment at NREL Advancing Renewable Energy and Energy Efficiency at Speed and Scale Prepared for the State Energy Advisory Board NREL is a national laboratory of the U.S. Department of Energy, Office of Energy Efficiency & Renewable Energy, operated by the Alliance for Sustainable Energy, LLC. Management Report NREL/MP-6A42-51947 May 2011 Contract No. DE-AC36-08GO28308 NOTICE This report was prepared as an account of work sponsored by an agency of the United States government. Neither the United States government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States government or any agency thereof. Available electronically at http://www.osti.gov/bridge Available for a processing fee to U.S. Department of Energy and its contractors, in paper, from: U.S. Department of Energy Office of Scientific and Technical Information P.O. Box 62 Oak Ridge, TN 37831-0062 phone: 865.576.8401 fax: 865.576.5728 email: mailto:[email protected] Available for sale to the public, in paper, from: U.S.
    [Show full text]
  • Transitioning to Solar Power: a Residential Guide to Alternative Energy Technology
    Transitioning to Solar Power: A Residential Guide to Alternative Energy Technology This guide will help prepare Irving residents to navigate and communicate with residential solar energy providers. The guide does not make recommendation or endorsements, but provides defined objectives and facts to help residents speak with solar providers and gather enough information to make an informed decision. It’s possible that residents may work through this guide and conclude that solar is not their best option. Considering solar energy? There are many reasons for choosing solar power. Residents should understand the specific reasons before speaking with a residential solar adviser. By having a clear understanding, residents can make an informed decision tailored to them. What are the expectations for a solar energy system? Residents should also define their expectations before speaking with a potential provider. There will always be some compromises, but knowing their expectations should help when deciding on the best option. Some examples may include: To reduce residents’ average electricity bill. To be off the grid. To be an environmental steward. To reduce a home’s carbon footprint. To provide a return for producing excess electricity. These are just some examples of the expectations residents may have when considering a solar energy system. No one system will be a perfect match for all consumers. Home retention and ownership This is an important aspect to consider when weighing energy efficiency options. Most of the financial justifications that will be presented will take about 15 to 30 years for a true payback. Residents should consider how long they anticipate living in their home to determine how a solar power system will be funded and financed.
    [Show full text]
  • Concentrating Solar Power: Energy from Mirrors
    DOE/GO-102001-1147 FS 128 March 2001 Concentrating Solar Power: Energy from Mirrors Mirror mirror on the wall, what's the The southwestern United States is focus- greatest energy source of all? The sun. ing on concentrating solar energy because Enough energy from the sun falls on the it's one of the world's best areas for sun- Earth everyday to power our homes and light. The Southwest receives up to twice businesses for almost 30 years. Yet we've the sunlight as other regions in the coun- only just begun to tap its potential. You try. This abundance of solar energy makes may have heard about solar electric power concentrating solar power plants an attrac- to light homes or solar thermal power tive alternative to traditional power plants, used to heat water, but did you know there which burn polluting fossil fuels such as is such a thing as solar thermal-electric oil and coal. Fossil fuels also must be power? Electric utility companies are continually purchased and refined to use. using mirrors to concentrate heat from the sun to produce environmentally friendly Unlike traditional power plants, concen- electricity for cities, especially in the trating solar power systems provide an southwestern United States. environmentally benign source of energy, produce virtually no emissions, and con- Photo by Hugh Reilly, Sandia National Laboratories/PIX02186 Photo by Hugh Reilly, This concentrating solar power tower system — known as Solar Two — near Barstow, California, is the world’s largest central receiver plant. This document was produced for the U.S. Department of Energy (DOE) by the National Renewable Energy Laboratory (NREL), a DOE national laboratory.
    [Show full text]
  • Radiation-Thermodynamic Modelling and Simulating the Core of a Thermophotovoltaic System
    energies Article Radiation-Thermodynamic Modelling and Simulating the Core of a Thermophotovoltaic System Chukwuma Ogbonnaya 1,2,* , Chamil Abeykoon 3, Adel Nasser 1 and Ali Turan 4 1 Department of Mechanical, Aerospace and Civil Engineering, The University of Manchester, Manchester M60 1QD, UK; [email protected] 2 Faculty of Engineering and Technology, Alex Ekwueme Federal University, Ndufu Alike Ikwo, Abakaliki PMB 1010, Nigeria 3 Department of Materials, Aerospace Research Institute, The University of Manchester, Manchester M13 9PL, UK; [email protected] 4 Independent Researcher, Manchester M22 4ES, Lancashire, UK; [email protected] * Correspondence: [email protected]; Tel.: +44-016-1306-3712 Received: 31 October 2020; Accepted: 20 November 2020; Published: 23 November 2020 Abstract: Thermophotovoltaic (TPV) systems generate electricity without the limitations of radiation intermittency, which is the case in solar photovoltaic systems. As energy demands steadily increase, there is a need to improve the conversion dynamics of TPV systems. Consequently, this study proposes a novel radiation-thermodynamic model to gain insights into the thermodynamics of TPV systems. After validating the model, parametric studies were performed to study the dependence of power generation attributes on the radiator and PV cell temperatures. Our results indicated that a silicon-based photovoltaic (PV) module could produce a power density output, thermal losses, 2 2 and maximum voltage of 115.68 W cm− , 18.14 W cm− , and 36 V, respectively, at a radiator and PV cell temperature of 1800 K and 300 K. Power density output increased when the radiator temperature increased; however, the open circuit voltage degraded when the temperature of the TPV cells increased.
    [Show full text]
  • Is Solar Power More Dangerous Than Nuclear?
    Is Solar Power More Dangerous Than Nuclear? by Herbert Inhaber Consider a massive nuclear power plant, closely guarded and surrounded by barbed wire. Compare this with an innocuous solar panel perched on a roof, cheerfully and silently gathering sunlight. Is there any question in your mind which of the two energy systems is more dangerous to human health and safety? If the answer were a resounding "No", the matter could end there, and the editors would be left with a rather unsightly blank space in their journal. But research has shown that the answer should be a less dramatic but perhaps more accurate "maybe". How can this be? Consider another example. In the driveway we have two vehicles. One is a massive lorry, and the other a tiny Mini. Which of the two is more efficient7 No, not larger — more efficient. Their relative size is easy to judge, but efficiency involves the amount of petrol used, the distance travelled, as well as the weight carried. The moral? You can't judge the relative risk of an energy system merely by its size or fearsome appearance. You must find the risk per unit energy — that is, its total risk to human health divided by the net energy it produces. This is the only fair way of comparing energy systems. In addition, we must consider the total energy cycle, not one isolated component. If you calculate the risk of only part of a system and compare it with the corresponding part of another, by judiciously choosing the component you could prove that any energy system is riskier (or safer) than any other system.
    [Show full text]
  • Solar Power History Pros and Cons
    Solar Power History Solar energy is the most readily available source of energy on the planet. Every hour the sun sends enough energy to power the entire planet for a year! Capturing the sun’s energy to do work for us began in the 7th century BCE when magnifying lenses were used to light fires. In the 18th and 19th century, solar technology really began to heat up with the invention of solar ovens and the discovery of the photovoltaic effect (the creation of electric current in a material upon exposure to light). During the late 1800’s and throughout the 1900’s, three different solar technologies emerged: solar photovoltaics , concentrating solar power and passive solar (discussed more below). In the early 1960's satellites in the United States and Soviet space programs were powered by solar cells and in the late 1960's solar power was basically the standard for powering space bound satellites. The period from the 1970's to the 1990's saw a change in the use of solar cells. Solar cells began powering railroad crossing signals and in remote places to help power homes, Australia used solar cells in their microwave towers to expand their telecommunication capabilities. Desert regions used solar power to assist with irrigation, when other means of power were not available. Today, you may see solar powered cars and solar powered aircraft. Recently new technology has provided such advances as screen printed solar cells. There is now a solar fabric that can be used to side a house and solar shingles for roofing.
    [Show full text]
  • Hybrid Floating Solar Plant Designs: a Review
    energies Review Hybrid Floating Solar Plant Designs: A Review Evgeny Solomin 1,*, Evgeny Sirotkin 1 , Erdem Cuce 2,3, Shanmuga Priya Selvanathan 4 and Sudhakar Kumarasamy 1,5,6,* 1 Department of Electric Power Stations, Network and Supply Systems, South Ural State University, 76 Prospekt Lenina, 454080 Chelyabinsk, Russia; [email protected] 2 Department of Mechanical Engineering, Faculty of Engineering, Recep Tayyip Erdogan University, Zihni Derin Campus, Rize 53100, Turkey; [email protected] 3 Low/Zero Carbon Energy Technologies Laboratory, Faculty of Engineering, Recep Tayyip Erdogan University, Zihni Derin Campus, Rize 53100, Turkey 4 Department of Chemical Engineering, Manipal Institute of Technology, Manipal Academy of Higher Education, Manipal 576104, India; [email protected] 5 Faculty of Mechanical and Automotive Engineering Technology, Universiti Malaysia Pahang (UMP), Pekan 26600, Malaysia 6 Energy Centre, Maulana Azad National Institute of Technology, Bhopal 462003, India * Correspondence: [email protected] (E.S.); [email protected] (S.K.) Abstract: The world’s demand for electricity will double by 2050. Despite its high potential as an eco- friendly technology for generating electricity, solar energy only covers a small percentage of the global demand. One of the challenges is associated with the sustainable use of land resources. Floating PV (FPV) plants on water bodies such as a dam, reservoir, canal, etc. are being increasingly developed worldwide as an alternative choice. In this background, the purpose of this research is to provide an outline of the hybrid floating solar system, which can be used to generate renewable energy. The hybrid technologies discussed include: FPV + hydro systems, FPV + pumped hydro, FPV + wave Citation: Solomin, E.; Sirotkin, E.; energy converter, FPV + solar tree, FPV + tracking, FPV + conventional power, FPV + hydrogen.
    [Show full text]
  • Residential Consumer Guide to Solar Power June 2018
    Residential Consumer Guide to Solar Power June 2018 Residential Consumer Guide to Solar Power June 2018 www.seia.org 1 Residential Consumer Guide to Solar Power June 2018 utility, the differences among those options, and Introduction selecting the right one for you. The main options Solar energy use has grown rapidly over the past available today are bulleted here and explained decade. Costs have dropped, while new ownership further below: and financing models allow more Americans than • Purchase a solar system (with cash or a loan) ever to choose solar. Solar is now available as a and own both the system and all the power it power choice in all fifty states, territories and the produces District of Columbia. Going solar is a significant • Lease a system, usually for a monthly rate, and decision. By understanding the basics of solar energy, own all the power it produces your solar options, and the right questions to ask solar professionals, you’re well positioned to make • Enter a “power purchase agreement” (PPA) the right decisions. to buy (in price per kWh) the electricity the system produces How Solar Works Purchase Today, most residential solar systems are photovoltaic (“PV”) – or solar electric – systems. This guide covers You can purchase a solar system outright with cash only PV systems. They generate electricity using two or a loan. When you buy a system, you are the main hardware components: owner of the system and benefit from all electricity it produces. You are usually responsible for system • Panels (or modules) that convert sunlight to upkeep, although most residential solar systems electricity; and require no to low maintenance, and some providers • Inverter(s) that convert(s) direct current to offer maintenance services on purchased systems.
    [Show full text]
  • Renewable Energy Fact Sheet
    ENVIRONMENTAL AND ENERGY STUDY INSTITUTE 122 C STREET, N.W., SUITE 630 WASHINGTON, D.C., 20001 202-628-1400 www.eesi.org Renewable Energy Fact Sheet Contact: CAROL WERNER Release: May 2006 Fredric Beck (202) 662-1892, [email protected] EXECUTIVE DIRECTOR Concentrating Solar Power Focusing the sun’s energy with mirrors to produce electricity Key Facts ¾ Concentrating solar power (CSP) technologies use mirrors to focus the sun’s heat. This heat is used to boil water, and the resulting steam turns a turbine to generate electricity. ¾ Concentrating solar power plants provide the lowest cost power of any solar technology. They can produce electricity for $0.09 to $0.12 per kilowatt-hour (kWh), which can be competitive with peak power prices. ¾ About 500 megawatts (MW) of concentrating solar power capacity will be installed worldwide by the end of 2005, according to the US Department of Energy. The world’s largest solar facility, a 345 MW CSP trough system, has been operating in the Mojave Desert in California since 1984. ¾ The United States has enormous solar energy potential. For example, a 100 mile by 100 mile plot of land in Nevada, fitted with CSP trough systems, could provide enough electricity for the entire United States, according to the National Renewable Energy Laboratory. Concentrating Solar Technology ¾ Trough systems: Using long, curved mirrors, trough systems concentrate solar energy onto oil-filled pipes, heating the oil. This hot oil is used to boil water, creating steam to turn a turbine. Heat can be stored in the oil, so trough systems can continue to generate power for several hours after dark or in cloudy weather.
    [Show full text]
  • The History of Solar
    Solar technology isn’t new. Its history spans from the 7th Century B.C. to today. We started out concentrating the sun’s heat with glass and mirrors to light fires. Today, we have everything from solar-powered buildings to solar- powered vehicles. Here you can learn more about the milestones in the Byron Stafford, historical development of solar technology, century by NREL / PIX10730 Byron Stafford, century, and year by year. You can also glimpse the future. NREL / PIX05370 This timeline lists the milestones in the historical development of solar technology from the 7th Century B.C. to the 1200s A.D. 7th Century B.C. Magnifying glass used to concentrate sun’s rays to make fire and to burn ants. 3rd Century B.C. Courtesy of Greeks and Romans use burning mirrors to light torches for religious purposes. New Vision Technologies, Inc./ Images ©2000 NVTech.com 2nd Century B.C. As early as 212 BC, the Greek scientist, Archimedes, used the reflective properties of bronze shields to focus sunlight and to set fire to wooden ships from the Roman Empire which were besieging Syracuse. (Although no proof of such a feat exists, the Greek navy recreated the experiment in 1973 and successfully set fire to a wooden boat at a distance of 50 meters.) 20 A.D. Chinese document use of burning mirrors to light torches for religious purposes. 1st to 4th Century A.D. The famous Roman bathhouses in the first to fourth centuries A.D. had large south facing windows to let in the sun’s warmth.
    [Show full text]
  • Exploring Solar Energy Student Guide
    U.S. DEPARTMENT OF Energy Efficiency & ENERGY EDUCATION AND WORKFORCE DEVELOPMENT ENERGY Renewable Energy Exploring Solar Energy Student Guide (Seven Activities) Grades: 5-8 Topic: Solar Owner: NEED This educational material is brought to you by the U.S. Department of Energy’s Office of Energy Efficiency and Renewable Energy. Name: fXPLORING SOLAR fNfRGY student Guide WHAT IS SOLAR ENERGY? Every day, the sun radiates (sends out) an enormous amount of energy. It radiates more energy in one second than the world has used since time began. This energy comes from within the sun itself. Like most stars, the sun is a big gas ball made up mostly of hydrogen and helium atoms. The sun makes energy in its inner core in a process called nuclear fusion. During nuclear fusion, the high pressure and temperature in the sun's core cause hydrogen (H) atoms to come apart. Four hydrogen nuclei (the centers of the atoms) combine, or fuse, to form one helium atom. During the fusion process, radiant energy is produced. It takes millions of years for the radiant energy in the sun's core to make its way to the solar surface, and then ust a little over eight minutes to travel the 93 million miles to earth. The radiant energy travels to the earth at a speed of 186,000 miles per second, the speed of light. Only a small portion of the energy radiated by the sun into space strikes the earth, one part in two billion. Yet this amount of energy is enormous. Every day enough energy strikes the United States to supply the nation's energy needs for one and a half years.
    [Show full text]
  • Solar Thermophotovoltaics: Reshaping the Solar Spectrum
    Nanophotonics 2016; aop Review Article Open Access Zhiguang Zhou*, Enas Sakr, Yubo Sun, and Peter Bermel Solar thermophotovoltaics: reshaping the solar spectrum DOI: 10.1515/nanoph-2016-0011 quently converted into electron-hole pairs via a low-band Received September 10, 2015; accepted December 15, 2015 gap photovoltaic (PV) medium; these electron-hole pairs Abstract: Recently, there has been increasing interest in are then conducted to the leads to produce a current [1– utilizing solar thermophotovoltaics (STPV) to convert sun- 4]. Originally proposed by Richard Swanson to incorporate light into electricity, given their potential to exceed the a blackbody emitter with a silicon PV diode [5], the basic Shockley–Queisser limit. Encouragingly, there have also system operation is shown in Figure 1. However, there is been several recent demonstrations of improved system- potential for substantial loss at each step of the process, level efficiency as high as 6.2%. In this work, we review particularly in the conversion of heat to electricity. This is because according to Wien’s law, blackbody emission prior work in the field, with particular emphasis on the µm·K role of several key principles in their experimental oper- peaks at wavelengths of 3000 T , for example, at 3 µm ation, performance, and reliability. In particular, for the at 1000 K. Matched against a PV diode with a band edge λ problem of designing selective solar absorbers, we con- wavelength g < 2 µm, the majority of thermal photons sider the trade-off between solar absorption and thermal have too little energy to be harvested, and thus act like par- losses, particularly radiative and convective mechanisms.
    [Show full text]