Headquarters | Philadelphia, Pennsylvania |
---|---|
Region served | The Gambia |
Services | Electrification |
Website | powerupgambia |
Power Up Gambia (PUG) is a Philadelphia-based non-profit health care and environmental group that works in the Gambia, in West Africa. It was founded in 2006 by Kathryn Cunningham Hall, then a University of Pennsylvania undergraduate.
The organization's goal is to provide reliable electricity to health care facilities throughout the Gambia. They do so through the installation of solar panel systems and battery storage systems, providing power throughout the day. [1]
Power Up Gambia was founded in 2006 by Kathryn Cunningham Hall, an undergraduate at the University of Pennsylvania. [1] While traveling to Sulayman Junkung General Hospital in the Gambia, she saw the consequences of limited electricity for Gambian patients. She founded Power Up Gambia, which installed a solar system at that hospital. [2] [3] Since then, the group has grown and has completed a solar panel installation at a village clinic, Somita Community Clinic. PUG is looking to expand its organization beyond the Philadelphia area as it prepares for an installation at Bansang Hospital, one of the largest in the Gambia. [4] For her work Kathryn Hall was named as one of the 10 Outstanding Young Americans (2009) by the United States Junior Chamber (Jaycees). [5]
The organization is also working with the Gambian Technical Training Institute in Banjul, the capital, to develop a solar energy training program to support its efforts over the long term. [6]
Microgeneration is the small-scale generation of heat and electric power by individuals, small businesses and communities to meet their own needs, as alternatives or supplements to traditional centralized grid-connected power. Although this may be motivated by practical considerations, such as unreliable grid power or long distance from the electrical grid, the term is mainly used currently for environmentally-conscious approaches that aspire to zero or low-carbon footprints or cost reduction. It differs from micropower in that it is principally concerned with fixed power plants rather than for use with mobile devices.
A solar cell panel, solar electric panel, photo-voltaic (PV) module or solar panel is an assembly of photo-voltaic cells mounted in a framework for installation. Solar panels use sunlight as a source of energy to generate direct current electricity. A collection of PV modules is called a PV panel, and a system of PV panels is called an array. Arrays of a photovoltaic system supply solar electricity to electrical equipment.
Solar power in Australia is a fast growing industry. As of April 2022, Australia's over 3.12 million solar PV installations had a combined capacity of 26,093 MW photovoltaic (PV) solar power, of which at least 4,342 MW were installed in the preceding 12 months. In 2019, 59 solar PV projects with a combined capacity of 2,881 MW were either under construction, constructed or due to start construction having reached financial closure. Solar accounted for 9.9% of Australia's total electrical energy production in 2020.
Solar power in Germany consists almost exclusively of photovoltaics (PV) and accounted for an estimated 8.2 percent of the country's gross-electricity generation in 2019. About 1.5 million photovoltaic systems were installed around the country in 2014, ranging from small rooftop systems, to medium commercial and large utility-scale solar parks. Germany's largest solar farms are located in Meuro, Neuhardenberg, and Templin with capacities over 100 MW.
The developing nations of Africa are popular locations for the application of renewable energy technology. Currently, many nations already have small-scale solar, wind, and geothermal devices in operation providing energy to urban and rural populations. These types of energy production are especially useful in remote locations because of the excessive cost of transporting electricity from large-scale power plants. The applications of renewable energy technology has the potential to alleviate many of the problems that face Africans every day, especially if done in a sustainable manner that prioritizes human rights.
Solar power represented a very small part of electricity production in the United Kingdom until the 2010s when it increased rapidly, thanks to feed-in tariff (FIT) subsidies and the falling cost of photovoltaic (PV) panels.
Solar power includes utility-scale power plants as well as local distributed generation, mostly from rooftop photovoltaics and increasingly from community solar arrays. From January through December 2021, utility-scale solar power generated 114.7 terawatt-hours (TWh), or 2.79% of all generated electrical energy in the United States. During the same time period total solar generation, including estimated small-scale photovoltaic generation, was 163.7 TWh.
A photovoltaic system, also PV system or solar power system, is an electric power system designed to supply usable solar power by means of photovoltaics. It consists of an arrangement of several components, including solar panels to absorb and convert sunlight into electricity, a solar inverter to convert the output from direct to alternating current, as well as mounting, cabling, and other electrical accessories to set up a working system. It may also use a solar tracking system to improve the system's overall performance and include an integrated battery.
The nominal power is the nameplate capacity of photovoltaic (PV) devices, such as solar cells, modules and systems, and is determined by measuring the electric current and voltage in a circuit, while varying the resistance under precisely defined conditions. The nominal power is important for designing an installation in order to correctly dimension its cabling and converters.
Solar power in California includes utility-scale solar power plants as well as local distributed generation, mostly from rooftop photovoltaics. It has been growing rapidly because of high insolation, community support, declining solar costs, and a Renewable Portfolio Standard which requires that 33% of California's electricity come from renewable resources by 2020, and 60% by 2030. Much of this is expected to come from solar power via photovoltaic facilities or concentrated solar power facilities.
Renewable energy in Tuvalu is a growing sector of the country's energy supply. Tuvalu has committed to sourcing 100% of its electricity from renewable energy. This is considered possible because of the small size of the population of Tuvalu and its abundant solar energy resources due to its tropical location. It is somewhat complicated because Tuvalu consists of nine inhabited islands. The Tuvalu National Energy Policy (TNEP) was formulated in 2009, and the Energy Strategic Action Plan defines and directs current and future energy developments so that Tuvalu can achieve the ambitious target of 100% renewable energy for power generation by 2020. The program is expected to cost 20 million US dollars and is supported by the e8, a group of 10 electric companies from G8 countries. The Government of Tuvalu worked with the e8 group to develop the Tuvalu Solar Power Project, which is a 40 kW grid-connected solar system that is intended to provide about 5% of Funafuti’s peak demand, and 3% of the Tuvalu Electricity Corporation's annual household consumption.
Sunetric is a Hawaii-based photovoltaic solar power company that performs consultation, design, and installation of photovoltaic systems for residential, commercial, military, and non-profit customers. Sunetric operates on all of the Hawaiian islands and in several states in the continental US. The company was founded in 2004 as Suntech Hawaii by Sean Mullen. Alex Tiller is the company's CEO. The company handles system consulting, design, and installation, and remains responsible for maintenance, monitoring, and repairs.
Public expenditure on health in the Gambia was at 1.8% of the GDP in 2004, whereas private expenditure was at 5.0%. There were 11 physicians per 100,000 persons in the early 2000s. Life expectancy at birth was 59.9 for females in 2005 and for males 57.7.
Solar power in Kentucky has been growing in recent years due to new technological improvements and a variety of regulatory actions and financial incentives, particularly a 30% federal tax credit, available through 2016, for any size project. Kentucky could generate 10% of all of the electricity used in the United States from land cleared from coal mining in the state. Covering just one-fifth with photovoltaics would supply all of the state's electricity.
Solar power in Rhode Island has become economical due to new technological improvements and a variety of regulatory actions and financial incentives, particularly a 30% federal tax credit, available through 2016, for any size project. A typical residential installation could pay for itself in utility bill savings in 14 years, and generate a profit for the remainder of its 25 year life. Larger systems, from 10 kW to 5 MW, receive a feed-in tariff of up to 33.45¢/kWh.
Solar power in West Virginia on rooftops can provide 23% of all electricity used in West Virginia from 6,300 MW of solar panels, but West Virginia will be the last state in the United States to reach grid parity - the point where solar panels are cheaper than grid electricity - without incentives, due to the low cost of electricity - about $0.062/kWh. The point where grid parity is reached is a product of the average insolation and the average cost of electricity. At $0.062/kWh and 4.3 sun-hours/day, solar panels would need to come down to ~$1,850/kW installed to achieve grid parity. The first state in the US to achieve grid parity was Hawaii. Solar power's favorable carbon footprint compared to fossil fuels is a major motivation for expanding renewable energy in the state, especially when compared to coal to generate electrical power.
Solar power in New Hampshire provides a small percentage of the state's electricity. State renewable requirements and declining prices have led to some installations. Photovoltaics on rooftops can provide 53.4% of all electricity used in New Hampshire, from 5,300 MW of solar panels, and 72% of the electricity used in Concord, New Hampshire. A 2016 estimate suggests that a typical 5 kW system costing $25,000 before credits and utility savings will pay for itself in 9 years, and generate a profit of $34,196 over the rest of its 25-year life. A loan or lease provides a net savings each year, including the first year. New Hampshire has a rebate program which pays $0.75/W for residential systems up to 5 kW, for up to 50% of the system cost, up to $3,750. However, New Hampshire's solar installation lagged behind nearby states such as Vermont and New York, which in 2013 had 10 times and 25 times more solar, respectively.
Solar power in Pennsylvania currently provides less than 1% of the state's electricity, but there are many policies in place to regulate and incentivize its use. Pennsylvania mandates the use of solar power through a renewable portfolio standard, which requires a percentage of electricity from each providers to come from solar, and net metering, which compensates small-scale solar generation through net metering. By 2021, Pennsylvania was required to have 0.5% of its electricity from solar. Their following goal is 10% by 2030. Solar power could theoretically provide over 30% of the state's electricity, but growth in solar generation has slowed due to a reduction in solar grants and the low price of solar energy credits. Efforts have also seen blowback from citizens, most notably from Mount Joy Township. Although, Pennsylvania has ruled solar as a legal use, meaning local governments can only restrict size and placement, but can't disband the projects.
Solar power in Tennessee is capable of producing much of the state's electricity; however, the industry remains in early stages in the state. With 129 MW of solar power in 2015, Tennessee ranked 20th among states for installed solar capacity.
Lightsource BP, rebranded from Lightsource Renewable Energy in 2018, is the largest solar developer in Europe, and third largest in the world outside of China. Lightsource BP is a British company with headquarters in London, and offices in San Francisco, Philadelphia, Mumbai, New Delhi, Cairo, Melbourne, Amsterdam, Bath, Belfast and Dublin.