#Global Satellite Solar Panels And Array Market | Explore Tumblr posts and blogs

aerospace-and-defence · 8 months ago

Text

Exhaustive secondary research was done to collect information on the Satellite Solar Panels and Array Market, its adjacent markets, and its parent market. The next step was to validate these findings, assumptions, and sizing with industry experts across the value chain through primary research. Demand-side analyses were carried out to estimate the overall size of the market. Both, top-down and bottom-up approaches were employed to estimate the complete market size. Thereafter, market breakdown and data triangulation were used to estimate the size of segments and subsegments.

#Satellite Solar Panels And Array #Satellite Solar Panels And Array Market #Satellite Solar Panels And Array Industry #Global Satellite Solar Panels And Array Market #Satellite Solar Panels And Array Market Companies #Satellite Solar Panels And Array Market Size #Satellite Solar Panels And Array Market Share #Satellite Solar Panels And Array Market Growth #Satellite Solar Panels And Array Market Statistics

0 notes

platinumsolar · 1 year ago

Text

9 Interesting Facts About Solar Power

Harnessing energy from the sun's rays via solar installation Sydney is revolutionising the way we produce and consume electricity. This green energy alternative has gained tremendous popularity, especially among environmentally conscious individuals and businesses.

Here are some fascinating facts about the miraculous power derived from the sun you may not know about.

Ancient Beginnings

The concept of harnessing the sun's energy isn’t new. In the 7th Century BC, people used magnifying glass materials to concentrate the sun's rays into beams so hot, they could ignite a fire. Later, in 1767, Swiss scientist Horace-Bénédict de Saussure created the first solar oven, which used the sun's energy to heat food. This marked the beginning of human endeavours to utilise this abundant energy source, setting the foundation for modern-day technologies that transform sunlight into a variety of practical applications.

Photovoltaic Effect

In 1839, French physicist Alexandre Edmond Becquerel discovered the photovoltaic effect. This phenomenon occurs when certain materials produce electric current upon exposure to light. This discovery was the cornerstone for the development of photovoltaic cells, which convert sunlight into electricity. The innovation in photovoltaic cells led to the development of panels that can be seen on rooftops and in energy farms around the world.

Space Exploration

The use of photovoltaic cells went mainstream during the space race. In 1958, the Vanguard I satellite used a small photovoltaic array to power its radios. This was the first time sun-powered cells were used for non-terrestrial applications, proving their durability and reliability in harsh conditions. Following Vanguard I, most spacecraft, including the International Space Station, use sun-based energy systems, showcasing the power and reliability of harvesting energy from the sun.

Reduction in Costs

Over the past four decades, the cost of photovoltaic modules has dropped exponentially. The price decline has been so dramatic that it now costs less than 1% of what it did in the early 1980s. This reduction has made it feasible for more homes and businesses to adopt this renewable energy source. The affordability has resulted in an uptick in global demand, encouraging manufacturers to innovate further, which in turn drives prices down even more.

Employment Opportunities

The boom in the popularity of this renewable energy has significantly contributed to job creation. The industry not only generates power but also powers economies by creating jobs in manufacturing, project development, maintenance, and various other fields. It is estimated that millions of people globally are employed in the sector. As the market continues to grow, the sector promises to be a significant contributor to global employment.

Energy Storage

One of the challenges of utilising energy from the sun has been how to store it efficiently. Recent advancements in battery technology have made energy storage more practical. Nowadays, high-capacity batteries can store excess electricity generated during the day for use at night, making this form of renewable energy more versatile and reliable. As technology progresses, we can expect even more efficient storage solutions to emerge.

Surpassing Non-renewable Sources

In many parts of the world, the generation of electricity through photovoltaic cells has become cheaper than fossil fuels like coal and natural gas. This cost-effectiveness, along with environmental considerations, has been a driving factor in the rapid adoption of this renewable energy. Economists and energy experts believe that this trend will continue and that photovoltaic energy may become the most cost-effective source of energy on a global scale.

Environmental Impact

Harnessing energy from the sun has a significantly lower environmental impact compared to conventional energy sources. It helps in reducing greenhouse gas emissions, which are a leading cause of climate change. Moreover, it necessitates a lower amount of water for operations compared to nuclear and fossil fuel options, making it a more sustainable option. The adoption of sun-derived power can be a game-changer in the global effort to combat climate change and preserve our planet for future generations.

Capacity for Growth

Despite its rapid adoption, this renewable energy source still accounts for a small fraction of global electricity production. However, with constant technological advancements, it is estimated that by 2050, a substantial portion of the world's electricity could be generated through the sun's power. The growth potential is enormous. From the vast solar farms to the small rooftop setups, there is ample opportunity for expansion. The continued innovation and falling costs are likely to propel this growth, making it one of the most important energy sources of the future.

The journey from igniting fires with magnifying glasses in ancient times to powering homes and businesses with photovoltaic cells has been incredible. With its ancient beginnings, contributions to space exploration, cost reductions, employment generation, advancements in energy storage, and positive environmental impact, the energy derived from the sun holds a promising future. Through continued innovation and adoption, this renewable energy source has the potential to play a pivotal role in steering us towards a more sustainable and greener future.

#Solar Installation Sydney

0 notes

vrushali456 · 2 years ago

Text

Solar PV Panels Market Tracking Report Analysis 2023-2031

The Solar PV Panels Market was valued at USD 153.07 billion in 2022, and it is anticipated to increase at a CAGR of 9.3% from 2023 to 2031. A solar panel, sometimes referred to as a PV panel, is made up of solar (or photovoltaic) cells that use the sun's light to produce energy. It is constructed from a number of silicon, boron, and phosphorus-based solar cells that are arrayed on the surface in a grid-like arrangement. Globally, the use of solar panels has grown due to the fact that they do not cause any pollution and that their installation aids in reducing the dangerous greenhouse gas emissions.

Get Sample Copy of this Reports@ https://www.econmarketresearch.com/request-sample/EMR005/

Top Key Players:

Market Growth:

The main use of photovoltaic or solar cells is to transform solar energy into an electron flow. These cells generate electricity from solar energy, which is useful for recharging batteries or powering devices. Spacecraft and orbiting satellites were first powered by solar cells. However, in recent years, their use for grid-connected electricity generation has increased. In order to function better, photovoltaic systems seek to maximize production. During the anticipated timeframe, these variables should accelerate market expansion.

Ask for Discount@ https://www.econmarketresearch.com/request-discount/EMR005/

Market Segmentation:

Solar PV Panels Market Size, Share & Trends Analysis Report, By Technology, By Grid Type, By Application By Region, And Segment Forecasts, 2023 – 2031

Market Drivers - Solar PV (Photovoltaic) panels market:

The industrial sector's rising demand for solar panels is evidence of the public's preference for alternative energy sources over traditional ones. Solar technology and panel installation are receiving significant investment from many sectors throughout the world. The rising number of solar power plants in various industry verticals is the main factor driving the global market for solar panels.

Market Opportunities - Solar PV (Photovoltaic) panels market

Solar cells, often known as photovoltaic cells, are used primarily to transform solar energy into an electron flow. These cells generate electricity from solar energy, which can be used to run devices or top off batteries. Initially, satellites in orbit and spacecraft were powered by photovoltaic cells.

Enquire Before Buy@ https://www.econmarketresearch.com/enquiry/EMR005/

About Us:

Econ Market Research is a one-stop provider of industry research and actionable intelligence. Through our syndicated and consulting research services, we help our clients get solutions to their research requirements. We specialise in industries such as semiconductors and Electronics, Aerospace and Défense, Energy, Automotive and Transportation, Healthcare, Manufacturing and Construction, Media and Technology, Chemicals, and Materials.

Contact Us:

If you have any queries about this report or if you would like further information, please contact us:

E-mail: [email protected]

Phone: (+1) 812 506 4440.

Website:- https://www.econmarketresearch.com

#Solar PV Panels Market #Solar PV Panels

0 notes

kennethresearch · 4 years ago

Text

Google Project Loon Market Size, Share, Development, Growth and Demand Forecast 2021 to 2025

Project Loon is a research and development project being developed by X (formerly Google X), which consists of a network of balloons equipped with routers at the edge of space. The aim of the project is to provide internet to everyone in the world. It is a known fact that many areas in the emerging and developed regions across the globe are deprived of a proper internet access.

Project Loon intends to connect people in rural and remote areas by making use of a network of internet-powered balloons traveling on the edge of space.

Google thinks its internet balloons will be a $10 billion business. Each balloon is equipped with LTE antennas capable of covering around 80 kilometers on the ground, a 100W solar panel array that charges a battery for nighttime operations, and additional antennas to relay traffic to other balloons.

Get Sample Reports Here - https://www.kennethresearch.com/report-details/google-project-loon-market/10065254

Assuming all the mechanisms of the project are functioning as planned, every single person can have access to internet. Loon's Use of Renewable Energy is an added advantage as it will greatly influence and inspire future projects. It creates an interplay between solar energy to keep the balloon functional while using wind energy to define its motor controls. With the constant connectivity to the each other through the internet collaboration between people across the globe will become much easier. The main problem with the Project Loon is the certainty of eventual hardware failure. If a Loon balloon fails, it can either remain up in the air floating, making it difficult to bring down or it might go down in unwanted areas as they can't be reached. Another concern over this project is internet privacy. As the project gives Google more power over a wider range of consumer behaviour the information obtained can become a security issue if it is shared with Government agencies.

Increasing the volume of internet users would invariably increase traffic on the world's leading search engine, Google Search. The increase in search users implies that more ads will be displayed which in turn result in profits for Google. Given the rising number of the mobile internet subscriptions and also the ever-increasing growth in the world population, the need for access to the internet is going to increase even more. The growing population, changing consumer internet habits and multiple developments via Internet-of-Things could drive the demand for a full-time easy access to the internet from every corner of the globe, which could be made possible by implementing Project Loon to its full potential.

Google has already run tests with several different telecoms. It has conducted test runs with Vodafone in New Zealand, Telstra in Australia, and Telefonica in Latin America - and is working on commercial deals with other new network operators. Google will split the revenue from any new customers with the telecommunications company providing the LTE spectrum.

SpaceX and Facebook are also working on similar projects and could be the potential competitors to Google. Facebook is the only company that has started testing its project by the use of unmanned aerial vehicles unlike SpaceX, which plans to provide a similar internet access facility by the use of a fleet of satellites.

Report Contents

Global Market segments

Global Market Drivers, Restraints and Opportunities

Global Market Size & Forecast 2016 to 2022

Supply & Demand Value Chain

Global Market - Current Trends

Competition & Major Companies

Technology and R&D Status

Porters Five Force Analysis

Strategic and Critical Success Factor Analysis of Key Players

Regional Analysis

North America

Latin America

Western Europe

Eastern Europe

Asia Pacific

Middle East and Africa

US and Canada

Mexico

Brazil

Argentina

Rest of Latin America

EU5 (Germany, France, Italy, Spain, U.K.)

Nordic Countries (Denmark, Finland, Norway, and Sweden)

Benelux (Belgium, The Netherlands, and Luxembourg)

Rest of Western Europe

Russia

Poland

Rest of Eastern Europe

China

India

Japan

Australia and New Zealand

Rest of Asia Pacific

GCC countries (Saudi Arabia, Oman, Qatar, Bahrain, UAE and Kuwait)

South Africa

North Africa

Rest of Middle East and Africa

Report Highlights

This report is an elaborate aggregation of primary inputs from industry experts and participants across the supply chain. It provides details on market segmentation which is derived from several product mapping exercises, macroeconomic parameters and other qualitative and quantitative insights. The impact of all such factors is delivered across multiple market segments and geographies.

Detailed Historical Overview (Market Origins, Product Launch Timeline, etc.)

Consumer and Pricing Analysis

Market dynamics of the industry

Market Segmentation

Estimated Market Sizing in terms of volume and value

Recent trends in market and impact

Research Status and Technology Overview

Extensive Industry Structure Coverage

About Kenneth Research

Kenneth Research is a reselling agency providing market research solutions in different verticals such as Automotive and Transportation, Chemicals and Materials, Healthcare, Food & Beverage and Consumer Packaged Goods, Semiconductors, Electronics & ICT, Packaging, and Others. Our portfolio includes set of market research insights such as market sizing and market forecasting, market share analysis and key positioning of the players (manufacturers, deals and distributors, etc), understanding the competitive landscape and their business at a ground level and many more. Our research experts deliver the offerings efficiently and effectively within a stipulated time. The market study provided by Kenneth Research helps the Industry veterans/investors to think and to act wisely in their overall strategy formulation

Contact Us

Name: David

Email : [email protected]

Phone: +1 313 462 0609

1412, Broadway,

21st Floor Suite MA111,

New York, NY 10018

1 note · View note

solaerotech-blog · 6 years ago

Link

SolAero Technologies Corp. is a leading provider of high efficiency solar cells, solar panels and composite structural products for satellite and aerospace applications. We provide solar power solutions and precision aerospace structures to the global space markets, encompassing a wide array of applications including civil space exploration, science and earth observation, defense intelligence and communication, and commercial telecommunications industries.

#satellite solar panels #space solar cells #satellite solar panels supplier #space solar cells supplier #Space 2.0 power solutions #Terrestrial solar cells

1 note · View note

thetejasamale · 2 years ago

Text

Utility Drones Market Growth Industry, Future, & Opportunity, Forecast till 2030

The global utility drones market is projected to be valued at USD 630.01 Million by 2025, with 35.42% CAGR during the forecast period, 2019–2025. Utility drones are unmanned aircraft that are used in utility industries. These drones provide services such as surveying, inspection, and maintenance of power generation and transmission and distribution systems across the world. The power components that are monitored include wind turbine farms and turbine blades, solar panel arrays, distribution and transmission cell towers, cooling towers and chimney, sub-stations, power lines, and other power distribution components.

The global utility drones market has been segmented into five regions, namely North America, Europe, Asia-Pacific, Middle East & Africa, and South America. North America is expected to hold the largest market share in the global utility drones market during the forecast period. Continuous investments in power infrastructure, increasing power consumption, and subsequently increasing focus on renewable power generation are the key factors driving the growth of utility drones in the region. The US accounted the largest market share in North America. For instance, In the US, Federal Aviation Administration has passed a regulation for commercial use of drones in the power sector. This is increasing the demand for commercial drones in the power and utility sector in the US and other countries in North America. Utility drones can be used effectively in managing power infrastructure assets. Inspection of power infrastructure by a drone consumes very little time when compared to time consumed in manual inspection of power infrastructure, thus saving man-hour and cost. This is leading to increasing demand for drones in managing power infrastructure assets in the US.

Browse Full Report Details @ https://www.marketresearchfuture.com/reports/utility-drones-market-8348

The utility drones market in Asia-Pacific is expected to be dominated by emerging economies such as China and India. Increasing private funding and investments in the development of power infrastructure, the establishment of long transmission lines, and the adoption of renewable energy sources are the primary factors that are likely to drive the utility drones market in the region.

The utility drones market in the Middle East & Africa is dominated by GCC (Gulf Cooperation Council) countries and South Africa due to the use of utility drones for media monitoring and as a traditional solution for satellites and helicopters in the UAE. However, according to a recent report by consulting firm strategy the market for drones in the Gulf Cooperation Council is expected to reach USD 1.5 billion by 2022.

The utility drones market in South America is dominated by Brazil, followed by Argentina, due to increasing expansion activities in the region. For instance, in 2018, HEMAV (Spain) approved an international expansion plan in Brazil, consolidating its presence in Peru, Ecuador, Colombia, Chile, and Argentina.

The global utility drones market has been segmented based on services, type, end use, and region. Based on services, the global market is divided into end-to-end solution and point solution. The end-to-end solution segment is expected to dominate the global market and is likely to grow with the highest CAGR. Based on type the global market is divided into multi-rotor and fixed-wing. The multi-rotor segment is expected to grow with the highest CAGR during the forecast period. Based on end use, the global market is bifurcated into conventional power and renewable. The conventional power segment is further sub-segmented into transmission & distribution (T&D) and generation. The renewable segment is further sub-segmented into solar and wind. The renewable segment is expected to hold the largest market share during the forecast period.

The global utility drones market is expected to grow at ~ 35.42% CAGR during the forecast period.

Key Players

The key players operating in the global utility drones market are Cyberhawk Innovations Limited (Scotland), PrecisionHawk (US), Delair (France), SkyScape Industries (US), Measure (US), Sharper Shape Inc. (US), Sky Futures (UK), Terra Drone (Japan), ABJ Drones (US), ULC Robotics (US), Aerodyne Group (Malaysia), Asset Drone (US), Hemav (Spain), YUNEEC (US), and DJI (China).

Scope of the Report

This report provides an in-depth analysis of the global utility drones market, tracking three market segments across five geographic regions. The report studies key players, providing a five-year annual trend analysis that highlights market size and shares for North America, Europe, Asia-Pacific, South America, and the Middle East & Africa. The report also presents a forecast, focusing on the market opportunities for the next five years for each region. The scope of the study segments the global utility drones market by services, type, end use, and region

Get FREE Sample@ https://www.marketresearchfuture.com/sample_request/8348

Services

End-to-End Solution

Point Solution

Type

Multi-Rotor

Fixed Wing

End-Use

Conventional Power

Renewable

Transmission & Distribution

Generation

Solar

Wind

By Region

North America

Asia-Pacific

Europe

Middle East & Africa

South America

#Utility Drones Market

0 notes

latestglobalmarketresearch · 3 years ago

Text

SATCOM Equipment Market for Space Is Growing Swiftly Due TO Increasing Demand from End Use Industry

The global SATCOM Equipment Market for Space is projected to grow from USD 2.8 billion in 2019 to USD 7.0 billion by 2025, at a CAGR of 16.8% from 2019 to 2025. The growth of the market across the globe can be attributed to the increasing launch of satellites for applications such as earth observation, communication, and navigation.

Browse 83 market data Tables and 40 Figures spread through 143 Pages and in-depth TOC on "SATCOM Equipment Market - Global Forecast to 2025"

Based on application, the earth observation & remote sensing segment is projected to lead the SATCOM equipment market for space during the forecast period.

Based on application, the SATCOM equipment market for space is projected to be led by the earth observation & remote sensing segment from 2019 to 2025. According to an article published by SpaceNews in December 2018, the demand for earth observation (EO) is growing, due to a growing focus on analytics from high-resolution and medium-resolution imagery. Technology for analyzing data gathered from EO satellites such as big data analytics is expected to grow four times over the decade.

The increasing use of CubeSats for earth observation and remote sensing is expected to drive the SATCOM equipment market for space from 2019 to 2025.

Based on satellite type, the CubeSat (0.25U–27U) segment is projected to grow at the highest CAGR during the forecast period. The SATCOM equipment market for CubeSats is expected to grow during the forecast period due to an increase in the volume of CubeSats launched and scheduled for launch during the forecast period. CubeSats are used for a variety of missions, have a small form factor, and cost substantially less to develop and launch in comparison to large satellites. The increase in the launch of CubeSats can be attributed to the rising demand for EO.

North America and Asia Pacific are projected to be high growth potential markets for SATCOM equipment for space during the forecast period.

The SATCOM equipment market for space in the North American region is expected to witness substantial growth during the forecast period due to increased launch and scheduled launch of satellites.

According to an article published in The New York Times in May 2019, SpaceX launched a batch of 60 internet communication satellites, as a part of the Starlink Megaconstellation Project. According to an article published by Future US, Inc., SpaceX has received permission from the Federal Communications Commission (FCC) to launch an estimated total of 12,000 Starlink satellites. Major players such as Amazon (US), OneWeb (US), and Telesat (Canada) are also expected to launch satellites during the forecast period.

Some of the major players in the SATCOM equipment market for space include Airbus SE (Netherlands), Maxar Technologies (US), Mitsubishi Electric Corporation (Japan), General Dynamics Corporation (US), Honeywell International Inc. (US), Harris Corporation (US), ISIS - Innovative Solutions in Space B.V. (Netherlands), and Oxford Space Systems (UK).

Mitsubishi Electric Corporation secures the third position in the SATCOM equipment market for space. The company has been contributing to space technology since 1960. It has a broad product portfolio and strong business performance. The company is constantly pushing for excellence, with a goal of achieving an operating income ratio of 8%, return on equity of 10% or more, and the ratio of interest-bearing debt to total assets of 15% or less by 2021. The company constantly innovates and brings new technologies to the market, with five new products launched in 2018. In July 2017, Mitsubishi Electric Corporation completed the construction of a facility that is expected to double the satellite component production capacity of the company. The facility is said to undertake the production and testing for solar array panels, structural panels, and other satellite components.

Get Sample Insights: https://www.marketsandmarkets.com/requestsampleNew.asp?id=177487346

About MarketsandMarkets™

MarketsandMarkets™ provides quantified B2B research on 30,000 high growth niche opportunities/threats which will impact 70% to 80% of worldwide companies’ revenues. Currently servicing 7500 customers worldwide including 80% of global Fortune 1000 companies as clients. Almost 75,000 top officers across eight industries worldwide approach MarketsandMarkets™ for their painpoints around revenues decisions.

Our 850 fulltime analyst and SMEs at MarketsandMarkets™ are tracking global high growth markets following the "Growth Engagement Model – GEM". The GEM aims at proactive collaboration with the clients to identify new opportunities, identify most important customers, write "Attack, avoid and defend" strategies, identify sources of incremental revenues for both the company and its competitors. MarketsandMarkets™ now coming up with 1,500 MicroQuadrants (Positioning top players across leaders, emerging companies, innovators, strategic players) annually in high growth emerging segments. MarketsandMarkets™ is determined to benefit more than 10,000 companies this year for their revenue planning and help them take their innovations/disruptions early to the market by providing them research ahead of the curve.

MarketsandMarkets’s flagship competitive intelligence and market research platform, "Knowledgestore" connects over 200,000 markets and entire value chains for deeper understanding of the unmet insights along with market sizing and forecasts of niche markets.

Contact: Mr. Aashish Mehra MarketsandMarkets™ INC. 630 Dundee Road Suite 430 Northbrook, IL 60062 USA : 1-888-600-6441

0 notes

gmiresearch · 3 years ago

Text

Metamaterial Market Research Report Analysis

Metamaterials Market

Growth opportunities in the Metamaterials Market look promising over the next six years. This is mainly due to their increasing demand for modeling & simulation to perform the various operation in industrial sectors and rising employment across major end-use sectors, including medical, aerospace and defense, consumer electronics, and automotive.

Request for a FREE Sample Report on Metamaterials Market

Metamaterials Market Dynamics (including market size, share, trends, forecast, growth, forecast, and industry analysis)

Key Drivers

Several prominent drivers stimulating the growth of the global metamaterials market include the increasing preference to implement these materials across several information and technology applications, augmenting demand for mirroring and reproducing of the devices for industrial purposes, and the surging emphasis on the introduction of effective solar power solution. Also, the mounting focus to employ the material across several healthcare and biomedical operations is strengthening the metamaterials market size. The material is further utilized for power plants, smart metamaterial antennas for 5G networks and satellites, and mechanically scanned array platforms for self-driving cars & drones will supplement the market share. However, as per the metamaterials market research, insufficient knowledge, excessive research, and design cost for successful execution in real-time functions and complexities concerned with design and fabrication may hinder the market growth.

Vertical Segment Drivers

Based on the Vertical, Aerospace and Defense is projected to expand at a higher CAGR during the forecast period. This is primarily attributed to their largest market size in terms of value. They mainly require customized solutions for communication. Also, the majorly endorsed metamaterial-based equipment are antennas, protective layers, windscreens, EMC shielding, and cloaking devices. These antennas can be applied for safe communications in the defense sector as they can be tuned to different bandwidths. Thus, the rising need for bandwidth and demand for secure communication further bolsters the market growth.

Application Segment Drivers

Based on the Application, Communication Antenna and Radar (BeamSteering) is expected to witness a faster CAGR during the forecast period. This is because of their soaring demand applications such as satellite communication, Wi-Fi routers, radar communication, and 5G communications.

Metamaterials Market’s leading Manufacturers:

· Mediwise

· Nanohmics Inc

· Echodyne Corp

· JEM Engineering

· Kymeta Corporation

· MetaShield LLC

· Multiwave Technologies AG

· TeraView Limited.

· Metamagnetics

· Kymeta Corporation

Metamaterials Market Segmentation:

Segmentation by Technology

· Electromagnetic

· Terahertz,Photonic (Optical)

· Tunable

· Frequency Selective Surface

· Other

Segmentation by Application

· Communication Antenna and Radar (BeamSteering)

· Sensors

· Solar Panel and Absorbers

· Display

· Medical

· Imaging

· Windscreen

· Other

Segmentation by Vertical

· Automotive

· Aerospace and Defense

· Consumer Electronics

· Medical

· Energy and Power

· Other

Segmentation by Region:

· North America

o United States of America

o Canada

· Asia Pacific

o China

o Japan

o India

o Rest of APAC

· Europe

o United Kingdom

o Germany

o France

o Spain

o Rest of Europe

· RoW

o Brazil

o South Africa

o Saudi Arabia

o UAE

o Rest of the world (remaining countries of the LAMEA region)

About GMI Research

GMI Research is a market research and consulting company that offers business insights and market research reports for large and small & medium enterprises. Our detailed reports help the clients to make strategic business policies and achieve sustainable growth in the particular market domain. The company's large team of seasoned analysts and industry experts with experience from different regions such as Asia-Pacific, Europe, North America, among others, provides a one-stop solution for the client. Our market research report has in-depth analysis, which includes refined forecasts, a bird's eye view of the competitive landscape, key factors influencing the market growth, and various other market insights to aid companies in making strategic decisions. Featured in the 'Top 20 Most Promising Market Research Consultants' list of Silicon India Magazine in 2018, we at GMI Research are always looking forward to helping our clients to stay ahead of the curve.

Media Contact Company Name: GMI RESEARCH Contact Person: Sarah Nash Email: [email protected] Phone: Europe – +353 1 442 8820; US – +1 860 881 2270 Address: Dublin, Ireland Website: www.gmiresearch.com

#Metamaterial Market #gmiresearch

0 notes

sundrenchednews · 5 years ago

Text

Solar Power is Coming to Space, According to the Airforce

In the race to replace traditional #energy methods with #solar energy, the United States is setting its sights on space. The Airforce Research Laboratory (AFRL) in Albuquerque is currently working on a #space-based solar energy satellite. In collaboration with Northrop Grumman, an American global aerospace and defense technology company, the AFRL is aiming to create a satellite system that will gather #solar energy from space, convert it into radio frequencies, and channel it back down to Earth. The primary goal is that the space-based #solar power project will provide energy for remote military base operations.

The project is known as the Space Solar Power Incremental Demonstration and Research project, or SSPIDR, and will cost more than $100 million to create and launch. AFRL’s Space Vehicles Director, Colonel Eric Felt, told the Albuquerque Journal that “to ensure Department of Defense mission success, we must have the energy we need at the right place at the right time.”

Major Tim Allen stated that the project is primarily to help replace convoy power deliveries used by troops. With the ability to send solar power from space to targeted areas, troops will no longer have to escort power convoys and are more likely to remain safe. The overall goal of the space-based solar system will be reliable, “wireless power transmission,” according to Allen.

Details of the Space-Based Solar Array

Developers of the AFRL space-based solar system are planning on creating a constellation of satellites with solar panels, spanning nearly 10,000-square meters across. The goal is that the solar energy gathered from the space structure can be targeted towards and electronically steered to specific locations. Rachel Delaney, the systems engineer for the space-based solar project, is currently working with a team to develop different demonstrations that will allow them to work out the details for a large-scale prototype.

Some of the biggest challenges Delaney and her team will face involve combating thermal damages that the solar structure may incur, as well as supporting a mammoth solar array of this size in orbit.

Increasing Interest in Space-Based Solar

Beaming solar energy from space back to Earth is not a new concept. In fact, the idea of space-based solar energy production has been around since the 1960s. However, it has not been a technologically realistic nor cost-effective possibility until recently. Part of the AFRL’s challenge in moving forward with space-based solar energy will be to find out just how cost-effective such an idea will be.

The good news is that with space-based solar energy, the solar panels can operate 24/7. According to Ali Hajimiri, an electrical engineering professor at the California Institute of Technology and director of their Space Solar Power Project, space-based solar has access to a constant power source. With no clouds, atmosphere, weather, or other obstructions, solar arrays in space can soak up the sun’s rays without interference or dependence on a day and night cycle.

Space-Based Solar: The Solution to Earth’s Energy Crisis?

Hajimiri, as well as other scientists and leaders that are pushing for space-based solar, are optimistic that we could test the first solar array in space within the next few years. Former NASA scientist, John Mankins, estimates that a space-based solar system could generate a constant flow of nearly 2,000 gigawatts of power. This is a massive upgrade in output compared to Earth’s largest solar production farm in Aswan, Egypt, which only produces 1.8 gigawatts of energy for the region.

If scientists can find a way to build a successfully space-based solar energy system that is both cost-effective and efficient, we could see “virtually limitless and sustainable energy” provided to various markets and cities worldwide, according to Mankins. Mankins warns, however, that other problems, such as geopolitics, could hinder progress.

Even though the AFRL space-based solar system will be used primarily for military operations, Delaney and Allen are hopeful that this solar project will be useful in the future for delivering solar energy to remote areas and other non-military communities around the world. Before long, we may just find that our energy on Earth is provided by space-based solar arrays floating in the atmosphere.

Resources:

https://www.abqjournal.com/1386648/afrl-looks-to-beam-solar-energy-from-space.html

https://www.forbes.com/sites/scottsnowden/2019/03/12/solar-power-stations-in-space-could-supply-the-world-with-limitless-energy/

0 notes

inerginc · 5 years ago

Link

An Oregon State University study, published in the journal Scientific Reports, has found that if less than 1% of agricultural land was converted to solar panels, it would be sufficient to fulfill the global electric energy demand.

The concept of co-developing the same area of land for both solar photovoltaic power and conventional agriculture is known as agrivoltaics.

“Our results indicate that there’s a huge potential for solar and agriculture to work together to provide reliable energy,” said corresponding author Chad Higgins, an associate professor in OSU’s College of Agricultural Sciences. “There’s an old adage that agriculture can overproduce anything. That’s what we found in electricity, too. It turns out that 8,000 years ago, farmers found the best places to harvest solar energy on Earth.”

The results have implications for the current practice of constructing large solar arrays in deserts, Higgins said.

“Solar panels are finicky,” he said. “Their efficiency drops the hotter the panels get. That barren land is hotter. Their productivity is less than what it could be per acre.”

For their study, OSU researchers analysed power production data collected by Tesla, which has installed five large grid-tied, ground-mounted solar electric arrays on agricultural lands owned by Oregon State. Specifically, the team looked at data collected every 15 minutes at the 35th Street Solar Array installed in 2013 on the west side of OSU’s Corvallis campus.

Related Stories: -Solar energy storage market to grow at over 35% -Thailand to boost floating solar on hydro dams -New York deploys its first intelligent solar mirror array -For the latest Solar and renewable energy news, updated daily, click here

The researchers synchronised the Tesla information with data collected by microclimate research stations they installed at the array that recorded mean air temperature, relative humidity, wind speed, wind direction, soil moisture and incoming solar energy.

Based on those results, Elnaz Hassanpour Adeh, a recent Ph.D. graduate from OSU’s water resources engineering programme and co-author on the study, developed a model for photovoltaic efficiency as a function of air temperature, wind speed and relative humidity.

“We found that when it’s cool outside the efficiency gets better,” Higgins said. “If it’s hot the efficiency gets worse. When it is dead calm the efficiency is worse, but some wind makes it better. As the conditions became more humid, the panels did worse. Solar panels are just like people and the weather, they are happier when it’s cool and breezy and dry.”

Using global maps made from satellite images, Adeh then applied that model worldwide, spanning 17 classes of globally accepted land cover, including classes such as croplands, mixed forests, urban and savanna. The classes were then ranked from best (croplands) to worst (snow/ice) in terms of where a solar panel would be most productive.

The model was then re-evaluated to assess the agrivoltaic potential to meet projected global electric energy demand that has been determined by the World Bank.

Higgins and Adeh previously published research that shows that solar panels increase agricultural production on dry, unirrigated farmland. Those results indicated that locating solar panels on pasture or agricultural fields could increase crop yields.

Co-authors on the recent study were Stephen Good, an assistant professor in OSU’s Department of Biological and Ecological Engineering, and Marc Calaf, an assistant professor of mechanical engineering at Utah State University.

You could search for stories like these, or you could have us send the latest in smart energy news sent you every day. Click below to subscribe.

Sign up to our newsletter

https://ift.tt/eA8V8J

#Solar #microgrids

0 notes

polixy · 6 years ago

Text

As debris piles up, Americans are skeptical enough will be done to limit space junk

As debris piles up, Americans are skeptical enough will be done to limit space junk;

A NASA-generated image of Earth depicts the many objects in geosynchronous orbit, about 22,000 miles above the surface. (NASA Orbital Debris Program Office)

Private companies such as SpaceX, Blue Origin and Virgin Galactic are becoming increasingly important players in space exploration. Many Americans are confident these companies will be profitable, but they’re more skeptical they will keep space clean of debris, according to a recent Pew Research Center survey.

Over the past 60 years, more than 5,250 space launches have spawned an orbital junkyard consisting of around 23,000 objects large enough to be detected, with a combined (Earth) weight of over 8,000 tons. While that’s a small amount compared with the more than 3.5 million tons of garbage the world produces every single day, it’s enough to pose a growing hazard to satellites and space stations.

There is at least one terrestrial clean-up strategy that could be applied to space junk: recycling. Among the estimated 4,500 satellites in orbit, only about 1,500 are still functional. But those roughly 3,000 dead satellites contain valuable components that could be repurposed for other uses. Some could be towed to Mars, to assist missions to the red planet, where they could be repaired. Other satellites with valuable building materials could be melted down by a solar-powered orbiting forge.

But most of the orbital debris is space-age flotsam and jetsam, such as spent rocket stages, screws and lens caps. There are about 23,000 detectable objects at least 2 to 4 inches in size in low-Earth orbit (the preferred altitude for most satellites and space missions) or about 1 to 3 feet in size in geostationary orbit (the ideal altitude for surveillance and communications satellites).

What’s more, these objects can create more pieces of debris when they collide with one another or explode in orbit, due to leftover fuel or battery failures. Around 290 such “fragmentation events” are known to have occurred since 1961, creating an estimated 750,000 objects larger than about 0.5 inches in size. Circling the Earth at speeds around 10 times faster than a bullet, the kinetic energy of even miniscule objects can pack a punch strong enough to puncture the hull of a space station or damage solar panels and communication arrays.

As more satellites are launched into space, the probability of collisions grows. There are, however, preventive measures that could mitigate the problem. For instance, engineers are developing technology to facilitate the venting of leftover fuel, thereby averting explosions in orbit. Or, satellites could be equipped with low-tech devices, such as balloons, that would enable Earth-based operators to guide them into the atmosphere – where they would burn up – at the end of their operational lifetimes.

Only 13% of Americans, however, have a great deal of confidence that space companies will sufficiently address the debris problem, while 51% have not too much or no confidence, according to a recent Pew Research Center survey. Yet, the same survey finds that, among the 7% of the public that is highly attentive to space news – those who say they have heard “a lot” about NASA in the past year and “a lot” about private space companies – some 37% have a great deal of confidence that private companies will minimize space debris.

Private companies might, in fact, profit from the growing need to eliminate existing space junk from Earth’s orbit. One recent business study estimates that the global market for monitoring and removing debris will generate $2.9 billion in revenue by 2022.

Technology for debris removal is currently being tested at the International Space Station. A satellite built by the British company Surrey Satellite Technology Limited, which is equipped with a harpoon and net, will test a system for capturing large pieces of space junk. At the end of its mission, it will unfurl a drag sail to slow its speed, bringing itself and the captured debris out of orbit, where it will burn up as it enters the atmosphere. No landfill required.

Topics: Emerging Technology Impacts, Science and Innovation, Energy and Environment

; Blog – Pew Research Center; http://www.pewresearch.org/fact-tank/2018/08/31/as-debris-piles-up-americans-are-skeptical-enough-will-be-done-to-limit-space-junk/; ; August 31, 2018 at 10:12AM

0 notes

usviraltrends-blog · 7 years ago

Photo

New Post has been published on https://usviraltrends.com/fleet-of-sailboat-drones-could-monitor-climate-changes-effect-on-oceans-science-15/

Fleet of sailboat drones could monitor climate change’s effect on oceans | Science

Carrying a suite of 15 instruments, saildrones 1005 and 1006 started their Pacific journey last September from Alameda, California.

Jennifer Keene, UW/JISAO and NOAA PMEL

By Paul VoosenMar. 8, 2018 , 11:00 AM

Two 7-meter-long sailboats are set to return next month to California, after nearly 8 months tacking across the Pacific Ocean. Puttering along at half-speed, they will be heavy with barnacles and other growth. No captains will be at their helms.

That is not because of a mutiny. These sailboats, outfitted with sensors to probe the ocean, are semiautonomous drones, developed by Saildrone, a marine tech startup based in Alameda, California, in close collaboration with the National Oceanic and Atmospheric Administration (NOAA) in Washington, D.C. The voyage is the longest test for the drones and also the first science test in the Pacific—an important step in showing that they could replace an aging and expensive array of buoys that are the main way scientists sniff out signs of climate-disrupting El Niño events.

After World War II, most sea surface data were collected from ships. Then came buoys and satellites. Now, NOAA scientists want to send in the drones. “We could be making the next epochal advancement in oceanography,” says Craig McLean, NOAA’s assistant administrator for oceanic and atmospheric research and acting chief scientist. Within the next decade, hundreds or even thousands of solar- and wind-powered drones could roam the world’s oceans, using satellites to relay information gathered from the sea surface and the air above.

The drones can’t come too soon for scientists who study the El Niño–Southern Oscillation, a set of shifting global temperature and rainfall patterns triggered by warm surface waters that slosh back and forth across the equatorial Pacific every few years. Since the 1980s, NOAA has supported a grid of buoys, moored to the Pacific sea floor, called the Tropical Atmosphere Ocean (TAO) array, to study and forecast these swings. Its success led to similar arrays in the Indian and Atlantic oceans.

But earlier this decade, the TAO array had a near-death experience. The marine growth on buoys and their moorings are fish magnets, which makes them a magnet for fishers as well, causing the distinctive TAO grid to appear on maps of global fish catches. As fishers dragged the buoys aside for easy pickings, they damaged them, and maintenance work began to pile up. Meanwhile, budget cuts and the soaring expense of operating research ships meant few new buoys were deployed. “That was a wake-up call for all of us,” says Christopher Sabine, an oceanographer at the University of Hawaii in Honolulu.

Winds of change

Two saildrones have carried a suite of 15 sensors into the tropical Pacific Ocean and back, powered only by the wind and sun. The data, relayed by satellites, are being compared to readings gathered by buoys and ships.

(GRAPHIC) A. CUADRA/SCIENCE; (DATA) SAILDRONE

Ultimately, Congress restored funding for the TAO array, which costs about $10 million a year. But now Japan, which maintains a complementary array in the western Pacific called the Triangle Trans-Ocean Buoy Network, has pulled out almost all of its buoys because of limited funds and a lack of ship time to maintain them, degrading El Niño measurements once again. The crises prompted NOAA and others to look for a more sustainable system to deliver El Niño warnings, which help agencies plan for the heavy rains and droughts that follow in its wake. “It’s an opportunity to look at exactly what the array is and its requirements are,” says Meghan Cronin, an oceanographer at NOAA’s Pacific Marine Environmental Laboratory (PMEL) in Seattle, Washington.

Richard Jenkins, an engineer and Saildrone’s founder, smelled an opportunity. He had built a sailboat on wheels called Greenbird that in 2009 broke the land-speed record for a wind-powered vehicle, reaching 202 kilometers per hour on a dry lake bed in Nevada. Afterward, he helped two ocean-minded philanthropists, Eric and Wendy Schmidt, outfit their research vessel, the R/V Falkor, at a cost of $60 million. He marveled at the expense and wondered whether a smaller, seafaring version of Greenbird could gather ocean data more cheaply. In theory, an ocean-going saildrone would need no fuel for propulsion; solar panels could power instruments and communications. Simply set waypoints and the drone would ride the wind there. The Schmidts gave Jenkins $2.5 million to get started; by 2013, a test craft had completed its first voyage from California to Hawaii, propelled by a 4.6-meter-tall carbon fiber composite sail.

Since then, Saildrone has worked with PMEL scientists to rig the boats with sensors and test their limits. In 2015, they survived 40-knot winds during a 3-month foray into the Arctic to assess marine life. That success encouraged scientists to mull whether the drones could help anchor observations in the Pacific. Conceivably, the drones could sail in circles around a virtual mooring point, or run other preplanned patterns, before returning to port every year for cleaning—no ships necessary. The drones could be cheaper, too. Saildrone charges $2500 a day per drone to collect data, whereas ship time can cost $30,000 or more per day. Jenkins thinks his drones can profit off that difference in the Pacific. “We are anticipating a fleet to service that market exclusively,” he says.

Where the drones sailed

Saildrone1005Saildrone1006Sea Surface Temperature 29.5˚C13.6˚CPacificOceanKm01000HawaiiSan Francisco

N. DESAI/SCIENCE; (DATA) SAILDRONE

The first Pacific test started on 5 September 2017, when two saildrones, 1005 and 1006, set out from San Francisco, California, for equatorial waters. Satellites had spotted cold tongues of surface water extending westward from the South American coast, an indicator of a strong La Niña, El Niño’s opposite number. It was not all smooth sailing. After arriving at the equator, the drones got stuck in the doldrums, a wind dead zone. “We knew the tropics were going to be a challenge,” Cronin says. (In July, another saildrone will depart for the tropics with a larger sail that Jenkins hopes will help it through the doldrums.)

Eventually, the saildrones caught the wind and escaped. And as Cronin looked back at the data from the cold tongues, she discovered a surprise: shifts in water temperature by 1° in less than a kilometer. “Some of these fronts are much sharper than you would ever imagine,” Cronin says. “That was shocking.” It is the type of detail a satellite’s lower resolution would smear out, and something a stationary buoy would have missed. Cronin says current climate models don’t account for these sharp gradients, which could churn the atmosphere above.

In addition to temperature, wind, and solar radiation data, the Pacific saildrones are measuring how the ocean and air exchange gases like carbon dioxide and oxygen, and they are using Doppler instruments to gauge currents coursing up to 100 meters below the surface. These sensors could reveal patterns that help explain why the tropical Pacific emits carbon dioxide, rather than absorbing it like most of the rest of ocean. Arrays like the TAO will continue to be important, Cronin says. But she foresees the emergence of a cheaper, more resilient oceanographic backbone. The new age of saildrones “is not going to solve all our problems,” Cronin says. “But it’s really interesting to think about doing oceanography without a ship.”

#Science

0 notes

caseinpoints · 7 years ago

Text

We’re entering PV3.0 and high-efficiency monocrystalline panel dominance

By Wenxue Li, president of LONGi Solar

The photovoltaic industry is undoubtedly at a turning point. High margins and low costs have made solar module technology cost-competitive in the energy economy and created a race-to-the-bottom phenomenon among panel manufacturers. While low costs are great for short-term market expansion, this focus on cheap materials compromises the quality and long-term reliability of modern solar assets, and the future viability of the industry as a whole.

Wenxue Li, president of LONGi Solar

In the United States, the pending Section 201 trade case has many buyers and sellers in the solar market confused as to what panel manufacturing will look like in the years ahead. The goals of the solar energy industry remain the same: to reduce carbon emissions, achieve grid parity for renewable resources and create resilient clean energy infrastructure. This point in solar history offers an opportunity for technology providers, project developers and asset owners to evaluate and understand strategies for deriving the largest value from solar projects. The highest energy yield and long-term resiliency of technologies are once again defining success in the new PV era: PV3.0, the era of the high-efficiency module.

The specific technology employed during different times of the PV evolution provides key insight into the historical transformation of the solar energy industry. In order for the solar industry to maintain its impressive worldwide growth and gain a foothold in emerging markets, the industry must understand these stages of evolution, including both their successes and setbacks. There have been three key eras: PV1.0, marked by the birth of the silicon PV cell and exploration around the application of clean energy; PV2.0, which brought about the global mass commercialization of solar and more affordable yet lower quality module technologies; and PV3.0, the era we are just now entering. Building on the technical and market knowledge gained during previous stages of PV development, PV3.0 realigns the industry using quality materials to achieve lasting high energy yields. To understand the future of solar panel technology, it is essential that we also reflect on all three stages of historical PV development.

Bell Labs created the first silicon photovoltaic cell in 1954, marking the beginning of the PV industry and first PV era, which would extend until 2000. Engineers and scientists discovered new applications for solar, from using PV technologies as the primary power source for earth-orbiting satellites to building panels into communication infrastructure systems. Then, in 1982, the first grid-connected photovoltaic project was established in Switzerland, which consisted of a 10-kW roof array using monocrystalline modules.

During this era, monocrystalline modules were largely the technology of choice. Defined by nearly perfect crystal structure and a homogenous crystalline framework, monocrystalline cells are single, continuous silicon crystals. This crystal purity results in high performance technology. For example, monocrystalline PV power plants built in the 1980s in Europe, the United States and Japan are still running today, well over 30 years later.

A central characteristic of the next era in solar panel technology development, PV2.0, is the feed-in tariff (FIT) program that powered photovoltaic markets in Germany and Europe. Policy makers across the world began creating new models to compensate solar developers and energy generators for the value they added to the grid, incentivizing the mass deployment of solar. The cumulative global installed PV capacity increased from 1,000 MW in PV1.0 to 300,000 MW throughout PV2.0.

Due to the increased market demand throughout PV2.0, more affordable polycrystalline modules took center stage and became the technology of choice for new installations. However, gradually there appeared to be several problems with this rapid development fixated on low-cost modules. Specifically, minimal product differentiation, low material reliability and serious system degradation threaten the health of the PV industry. The next stage of PV development must address these issues.

Fortunately, PV3.0 is now upon us. The solar market is maturing—the industry as a whole is no longer looking for quick fixes and, with 60 years of experience, now has the vantage point to appreciate the long-term value of solar assets. Low-cost solutions and the lower efficiency associated with them are unable to compete with the multiplying returns that high-quality technology offers. PV3.0 will be marked by a return to the high-yielding and reliable monocrystalline cell technology. Due to the higher efficiency associated with monocrystalline modules, developers can also pack the same amount of generating power into a smaller footprint. This translates into cost savings during project development, as high-quality modules allow for less labor, fewer materials and much less overall maintenance. There is also less degradation associated with monocrystalline technology, ensuring the longevity of projects and savings from delaying system replacements.

Research and development has played a central role to the technology advancements in each PV era, and continued investment in R&D will be essential to the solar industry’s competitiveness. Companies around the world are already seeing returns on these research and development investments and are producing high-efficiency, high-reliability and high-energy yield solar modules. Global policies are also changing in favor of monocrystalline; for example, under China’s 2017 “Top Runner Program,” feed-in-tariffs will favor high-efficiency projects. PV3.0 will seek to build upon and combine lessons learned in the past two solar technology eras to create win-win scenarios for all parties involved.

The solar industry’s continual evolution distinguishes it from other power generation industries. While photovoltaics have made great strides since their initial deployment more than five decades ago, there is still work to be done. A new era focused on the commercialization of high-efficiency modules promises to ensure the continued viability of solar power as a global power source.

Mr. Wenxue Li is the president of LONGi Solar. In 2010, he joined LONGi Silicon Materials (Ningxia), and since assuming leadership of LONGi Solar has overseen the company’s rapid growth and expansion, and made great contributions to upgrading corporate management and improving production efficiency and worker productivity. In the past year, LONGi has become one of the fastest growing PV manufacturers in the world, in addition to be named a tier one manufacturer by Bloomberg and appearing as the only new energy company on Goldman Sach’s ‘Nifty 50’ list of Chinese companies.

Solar Power World

0 notes

latestglobalmarketresearch · 3 years ago

Text

North America and Asia Pacific are projected to be high growth potential markets Over the Forecast Period

The global SATCOM Equipment Market for Space is projected to grow from USD 2.8 billion in 2019 to USD 7.0 billion by 2025, at a CAGR of 16.8% from 2019 to 2025. The growth of the market across the globe can be attributed to the increasing launch of satellites for applications such as earth observation, communication, and navigation.

Browse 83 market data Tables and 40 Figures spread through 143 Pages and in-depth TOC on "SATCOM Equipment Market - Global Forecast to 2025"

Based on application, the earth observation & remote sensing segment is projected to lead the SATCOM equipment market for space during the forecast period.

Based on application, the SATCOM equipment market for space is projected to be led by the earth observation & remote sensing segment from 2019 to 2025. According to an article published by SpaceNews in December 2018, the demand for earth observation (EO) is growing, due to a growing focus on analytics from high-resolution and medium-resolution imagery. Technology for analyzing data gathered from EO satellites such as big data analytics is expected to grow four times over the decade.

Browse In-depth Insights: https://www.marketsandmarkets.com/Market-Reports/space-satcom-equipment-market-177487346.html