Husk Power Systems

Last updated

Husk Power Systems
Industry Energy industry
Headquarters Fort Collins, Colorado, United States
Patna, Bihar, India
ProductsSolar and biomass rural microgrids / mini-grids
RevenueUS$ 10 million
Website https://huskpowersystems.com/

Husk Power Systems, founded in 2008, is a company based in Fort Collins, Colorado, US, that provides clean energy services to off-grid or weak grid rural communities in East Africa, West Africa and South Asia, primarily by building renewable energy mini-grids/micro-grids. Its original technology generated electricity using a biomass gasifier that created fuel from rice husks, a waste product of rice hullers that separate the husks as chaff from the rice, a staple food in both Asia and Africa. In the mid-2010s, with the rapid decline in the price of solar PV and batteries, Husk pivoted its business model [1] [2] to focus more on solar-plus-storage mini-grids (what at the time Husk coined "mini power plants"), while continuing to use biomass in combination with solar to serve communities with larger electricity demand. In 2021, Husk Power was recognized in the REN21 Renewables Global Status Report as the first mini-grid company to achieve significant scale, by surpassing 100 solar hybrid community mini-grids, and 5,000 small business customers. [3] In 2022, Husk signed an Energy Compact with the United Nations, in which it set a target of building 5,000 mini-grids and connecting at least 1 million customers by 2030. [4]

Contents

The company was co-founded by Manoj Sinha (currently CEO), Gyanesh Pandey, Ratnesh Yadav, and Chip Ransler. Chairman of the Board is Brad Mattson.[ citation needed ]

Need

According to the World Bank, about 800 million people worldwide have no access to electricity, [5] with the majority of those people located in Sub-Saharan Africa. Millions of people die each year as a result of indoor air pollution caused by the combustion of traditional fuels used for cooking, heating and lighting. [6] The largest population without electricity in Sub-Saharan Africa, about 90 million people, is in Nigeria, where both businesses and households are not connected to the electric grid, and even those who are connected often receive erratic service due to the lack of generating capacity. [6] For off-grid and weak grid areas, this absence of the grid has resulted in a massive diesel generation economy. [7] This scenario is repeated across Sub-Saharan Africa, parts of Southeast and South Asia and island states. The World Bank adds that mini-grids have the potential to serve 490 million people globally, and that achieving such scale would require 210,000 mini-grids and $220 billion. [8] Currently, the industry has attracted $5 billion, with 19,000 mini-grids built. [ check quotation syntax ]

Concept

Current CEO and co-founder Manoj Sinha, named one of the 2022 Global Energy Elites [9] and Meaningful Business 100 [10] for his pioneering work, was responsible for evolving Husk's approach to take advantage of the steep decline in solar prices. By adding solar to biomass, Husk was able to provide 24/7 100% renewable energy to its customers, using solar during daytime, biomass in the evening and batteries at night. According to a Harvard Business School Case Study: "From 2007 through 2013, Husk built 80 biomass waste (primarily rice husk from rice mills) plants that provided electricity to 250,000 villagers and shop owners spread across 350 villages in India and Africa. By 2015, Husk underwent a major pivot. Rather than a rural electrification vision aimed at providing power to rural households through biomass gasification alone, Sinha envisioned plants organized around village commercial customers that used biomass gasification, solar energy, and battery power in tandem, allowing for power generation nearly 24-7. To bring this vision to reality, Sinha ceased operations of nearly all of the existing plant locations and began the conversion to new locations built around the 'new' hybrid plant. Thus in 2015, Husk was operating a mere 10 power plants and serving roughly 2,000 customers, down from the 80 plants and roughly 250,000 customers they had prior to this shift." [2] In 2022, it had more 150 power plants in operation.

Founding CEO Gyanesh Pandey, an electrical engineer who graduated from Indian Institute of Technology (BHU) Varanasi and then earned a master's at Rensselaer Polytechnic Institute, left a job in the United States and returned to India. There he worked with Ratnesh Yadav on business ideas to serve the needs of the poor in India, with their initial unsuccessful ideas including the development of solar-powered lights and the use of jatropha seeds to create biodiesel fuel. After a chance meeting with a gasifier salesman, the two conceived of using rice husks, the unused detritus of the rice hulling process, as an input source. [11] Estimates are that 1.8 billion kilograms (4 billion pounds) of rice husks are left over from rice processing in Bihar each year and almost all of it had previously been used unproductively as there had been no uses identified for it. Pandey focused on the development of the circuitry that would allow the systems to most efficiently generate power, working with the Ministry of New and Renewable Energy to optimize the gasifier to use rice husks alone, then using the output of the gasifier to fuel a generator and assembling a crude local power distribution network that they built for the village of Tamkuha, which went live in August 2007. [6]

Application

Unlike solar home systems that provide basic services like lighting and phone charging, Husk Power serves the entire rural economy, with mini-grids at the center of the company's business model. It serves both completely rural off-grid areas, which have in the past only been able to use diesel generation to power their businesses and livelihoods, and it serves weak grid areas where the main grid (distribution companies or power utilities often referred to as "Discoms" in India, and "Discos" in Africa) provide unreliable and/or poor quality connections. Aside from building, owning and operating the power plant, Husk also builds and operates the transmission and distribution (T&D) network, which includes smart meters. The company has integrated internet of things (IoT) and machine learning into its infrastructure, which allows for largely automated operations as well as demand forecasting.

The solar hybrid microgrids developed by the company have an average generation capacity of 50 kW. Designed in a modular fashion, generation capacity can easily grow as demand grows. The electricity generated is able to power the needs of an entire community, including commercial and household demand, as well as "productive use" applications such as drinking water filtration and bottling, grain milling, welding, cold chain, etc. If the system adds gasification, the rice husks used to fuel the process are purchased from local rice mills. Based on experience in India and Nigeria, customers that switch from diesel generation to solar power from the mini-grids save about 30% on the monthly energy bill.

The revenue model for customers is pay-as-you-go. Payment is made digitally, thought the company's app, called Huskify, which also allows customers to see their energy usage in real time.

Besides providing electricity, Husk Power also provides financing to customers to purchase energy efficient appliances, either for household or commercial use. Because of its 15 years of experience in building mini-grids, Husk has also developed a robust engineering, procurement and construction (EPC) capacity, and leverages that to install turnkey rooftop solar systems for rural commercial and industrial customer (C&I) who want a captive system that is separate from the mini-grid.

Impact

Each microgrid connects hundreds of customers, including micro, small and medium-sized enterprises (MSMEs), households and institutions such as schools and health clinics, and benefits thousands more, through street lighting and other community-based services. Village life can go beyond daylime as shops can now stay open later, which promotes increased revenue. Students can also use the electricity generated to study into the night. Each plant provides local jobs, which creates opportunities for farmers and entrepreneurs. [12] Local residents are employed as technicians, salespeople and for plant security.

Finance

Husk Power has raised three rounds of equity to date, totalling about $30 million. In 2018, it raised a Series C equity totaling $20 million [13] from Shell Ventures, Swedfund International and Engie Rassembleurs d'Energies, with FMO coming in later with an additional $5 million. [14] Other investors have included The Rockefeller Foundation, Acumen, US International Development Finance Corp. and First Solar. In 2022, Husk also raised more than $10 million in debt for project financing in India, from EU-funded EDFI-ElectriFI and the India Renewable Energy Development Agency (IREDA).

Early on, Charles "Chip" Ransler and Manoj Sinha, then students at the Darden Graduate School of Business Administration at the University of Virginia, developed a business plan that earned $60,000 from social innovation competitions sponsored by Darden and by the University of Texas. [15] In 2009, the company won an inaugural global business plan competition sponsored by venture capital firm Draper Fisher Jurvetson and Cisco Systems and will receive a $250,000 investment from the two firms to help improve the basic technology that the firm has already developed. The company has since received two rounds of financing from the Shell Foundation. [6]

Service area

As of 2022, Husk Power Systems had nearly 150 operational renewable energy mini-grids in India, located in the states of Bihar and Uttar Pradesh. Solar PV serves customers during the day, with biomass providing up to eight hours of power, primarily during the evening hours. [16] [17] Battery power is available for nighttime use. The company is also planning further expansion to additional states in India, as well as other countries in Southeast Asia and Africa, where the combination of power shortages in rural areas and availability of ample sunshine and/or waste rice husks make the generating systems an effective solution. [16] In September 2023, at the Africa Climate Summit, Husk launched an initiative called 'Africa Sunshot,' aiming to install 2,500 solar minigrids over 5 years to supercharge low-carbon economic growth in rural Sub-Saharan Africa. [18] [19]

See also

Related Research Articles

<span class="mw-page-title-main">Electricity sector in India</span> Power generation and distribution

India is the third largest producer of electricity in the world. During the fiscal year (FY) 2022–23, the total electricity generation in the country was 1,844 TWh, of which 1,618 TWh was generated by utilities.

<span class="mw-page-title-main">Xcel Energy</span> American utility company

Xcel Energy Inc. is a U.S. regulated electric utility and natural gas delivery company based in Minneapolis, Minnesota, serving more than 3.7 million electric customers and 2.1 million natural gas customers across parts of eight states. It consists of four operating subsidiaries: Northern States Power-Minnesota, Northern States Power-Wisconsin, Public Service Company of Colorado, and Southwestern Public Service Co.

<span class="mw-page-title-main">Rural electrification</span> Bringing electrical power to rural areas

Rural electrification is the process of bringing electrical power to rural and remote areas. Rural communities are suffering from colossal market failures as the national grids fall short of their demand for electricity. As of 2019, 770 million people live without access to electricity – 10.2% of the global population. Electrification typically begins in cities and towns and gradually extends to rural areas, however, this process often runs into obstacles in developing nations. Expanding the national grid is expensive and countries consistently lack the capital to grow their current infrastructure. Additionally, amortizing capital costs to reduce the unit cost of each hook-up is harder to do in lightly populated areas. If countries are able to overcome these obstacles and reach nationwide electrification, rural communities will be able to reap considerable amounts of economic and social development.

<span class="mw-page-title-main">TANESCO</span>

The Tanzania Electric Supply Company Limited (TANESCO) is a Tanzanian parastatal organisation established in 1964. It is wholly owned by the government of Tanzania. The Ministry of Energy and Minerals regulates the operations of TANESCO.

The energy policy of India is to increase the locally produced energy in India and reduce energy poverty, with more focus on developing alternative sources of energy, particularly nuclear, solar and wind energy. Net energy import dependency was 40.9% in 2021-22.

<span class="mw-page-title-main">Ministry of New and Renewable Energy</span> Indian government ministry

The MINISTRY OF NEW AND RENEWABLE ENERGY (MNRE) is a ministry of the Government of India, headed by current Union Cabinet Minister Raj Kumar Singh, that is mainly responsible for research and development, intellectual property protection, and international cooperation, promotion, and coordination in renewable energy sources such as wind power, small hydro, biogas, and solar power.

For solar power, South Asia has the ideal combination of both high solar insolation and a high density of potential customers.

<span class="mw-page-title-main">Renewable energy in Africa</span> Renewable energy in Africa

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.

<span class="mw-page-title-main">Energy in India</span> Overview of the production, consumption, import and export of energy and electricity in India

Since 2013, total primary energy consumption in India has been the third highest in the world after China and United States. India is the second-top coal consumer in the year 2017 after China. India ranks third in oil consumption with 22.1 crore tons in 2017 after United States and China. India is net energy importer to meet nearly 47% of its total primary energy in 2019.

<span class="mw-page-title-main">Renewable energy in developing countries</span> Overview of the use of renewable energy in several developing countries

Renewable energy in developing countries is an increasingly used alternative to fossil fuel energy, as these countries scale up their energy supplies and address energy poverty. Renewable energy technology was once seen as unaffordable for developing countries. However, since 2015, investment in non-hydro renewable energy has been higher in developing countries than in developed countries, and comprised 54% of global renewable energy investment in 2019. The International Energy Agency forecasts that renewable energy will provide the majority of energy supply growth through 2030 in Africa and Central and South America, and 42% of supply growth in China.

<span class="mw-page-title-main">Renewable energy in India</span>

India is world's 4th largest consumer of electricity and world's 3rd largest renewable energy producer with 40% of energy capacity installed in the year 2022 coming from renewable sources. Ernst & Young's (EY) 2021 Renewable Energy Country Attractiveness Index (RECAI) ranked India 3rd behind USA and China. In FY2023-24, India is planning to issue 50 GW tenders for wind, solar and hybrid projects. India has committed for a goal of 500 GW renewable energy capacity by 2030. In line with this commitment, India's installed renewable energy capacity has been experiencing a steady upward trend. From 94.4 GW in 2021, the capacity has gone up to 119.1 GW in 2023 as of Q4.

Energy use and development in Africa varies widely across the continent, with some African countries exporting energy to neighbors or the global market, while others lack even basic infrastructures or systems to acquire energy. The World Bank has declared 32 of the 48 nations on the continent to be in an energy crisis. Energy development has not kept pace with rising demand in developing regions, placing a large strain on the continent's existing resources over the first decade of the new century. From 2001 to 2005, GDP for over half of the countries in Sub Saharan Africa rose by over 4.5% annually, while generation capacity grew at a rate of 1.2%.

<span class="mw-page-title-main">Renewable energy in Nepal</span> Overview of renewable energy in Nepal

Renewable energy in Nepal is a sector that is rapidly developing in Nepal. While Nepal mainly relies on burning biomass for its energy needs, solar and wind power is being seen as an important supplement to solve its energy crisis. The most common form of renewable energy in Nepal is hydroelectricity.

Three primary energy sources make up the energy mix in Guinea: fossil biomass, oil and hydropower. Biomass makes the largest contribution in primary energy consumption. It is locally produced, while Guinea imports all the petroleum products it needs. The potential for hydroelectric power generation is high, but largely untapped. Electricity is not available to a high percentage of Guineans, especially in rural areas, and service is intermittent, even in the capital city of Conakry.

<span class="mw-page-title-main">Renewable energy in Kenya</span>

Most of Kenya's electricity is generated by renewable energy sources. Access to reliable, affordable, and sustainable energy is one of the 17 main goals of the United Nations’ Sustainable Development Goals. Development of the energy sector is also critical to help Kenya achieve the goals in Kenya Vision 2030 to become a newly industrializing, middle-income country. With an installed power capacity of 2,819 MW, Kenya currently generates 826 MW hydroelectric power, 828 geothermal power, 749 MW thermal power, 331 MW wind power, and the rest from solar and biomass sources. Kenya is the largest geothermal energy producer in Africa and also has the largest wind farm on the continent. In March 2011, Kenya opened Africa's first carbon exchange to promote investments in renewable energy projects. Kenya has also been selected as a pilot country under the Scaling-Up Renewable Energy Programmes in Low Income Countries Programme to increase deployment of renewable energy solutions in low-income countries. Despite significant strides in renewable energy development, about a quarter of the Kenyan population still lacks access to electricity, necessitating policy changes to diversify the energy generation mix and promote public-private partnerships for financing renewable energy projects.

<span class="mw-page-title-main">Renewable energy in Ethiopia</span>

Ethiopia generates most of its electricity from renewable energy, mainly hydropower.

In 2013, renewable energy provided 26.44% of the total electricity in the Philippines and 19,903 gigawatt-hours (GWh) of electrical energy out of a total demand of 75,266 gigawatt-hours. The Philippines is a net importer of fossil fuels. For the sake of energy security, there is momentum to develop renewable energy sources. The types available include hydropower, geothermal power, wind power, solar power and biomass power. The government of the Philippines has legislated a number of policies in order to increase the use of renewable energy by the country.

<span class="mw-page-title-main">Renewable energy in South Africa</span>

Renewable energy in South Africa is energy generated in South Africa from renewable resources, those that naturally replenish themselves—such as sunlight, wind, tides, waves, rain, biomass, and geothermal heat. Renewable energy focuses on four core areas: electricity generation, air and water heating/cooling, transportation, and rural energy services. The energy sector in South Africa is an important component of global energy regimes due to the country's innovation and advances in renewable energy. South Africa's greenhouse gas (GHG) emissions is ranked as moderate and its per capita emission rate is higher than the global average. Energy demand within the country is expected to rise steadily and double by 2025.

Clementine Chambon is a chemical engineer at Imperial College London, who works on energy solutions for energy-deprived countries. She is the Chief Technology Officer (CTO) of Oorja Development Solutions, a social enterprise that focused on providing clean energy access to off-grid communities in rural India.

A mini-grid is an aggregation of loads and one or more energy sources operating as a single system providing electric power and possibly heat isolated from a main power grid. A modern mini-grid may include renewable and fossil fuel-based generation, energy storage, and load control. A mini grid can be fully isolated from the main grid or interconnected to it. If it is interconnected to the main grid, it must also be able to isolate (“island”) from the main grid and continue to serve its customers while operating in an island or autonomous mode. Mini-grids are used as a cost-effective solution for electrifying rural communities where a grid connection is challenging in terms of transmission and cost for the end user population density, with mini grids often used to electrify rural communities of a hundred or more households that are 10 km or more from the main grid.

References

  1. "Husk Power - Case - Faculty & Research - Harvard Business School". www.hbs.edu. Retrieved 30 September 2021.
  2. 1 2 "Husk Power: Scaling the Venture - Case - Faculty & Research - Harvard Business School". www.hbs.edu. Retrieved 30 September 2021.
  3. "Renewables Global Status Report" (PDF). Renewables Global Status Report: 170. 2021 via REN21.
  4. Nations, United. "Energy Compacts Registry". United Nations. Retrieved 24 January 2022.
  5. Staff." https://www.worldbank.org/en/topic/energy/overview#1 World Bank, 2019.
  6. 1 2 3 4 Borenstein, David. "A Light in India", The New York Times , January 10, 2011. Retrieved January 12, 2011.
  7. "Jobs or just lights? Nigeria toils to power up its solar promise | Context". www.context.news. Retrieved 28 October 2022.
  8. "Mini Grids for Half a Billion People: Market Outlook and Handbook for Decision Makers". World Bank. Retrieved 24 January 2022.
  9. "MANOJ SINHA". Global Power And Energy Elites. Retrieved 24 January 2022.
  10. "Manoj Sinha". Meaningful Business Community. Retrieved 28 October 2022.
  11. Revkin, Andrew C. "Husk Power for India", The New York Times , 24 December 2008. Retrieved 12 January 2011.
  12. "Community Impact". Husk Power Systems. Archived from the original on 20 February 2015. Retrieved 8 December 2015.
  13. "Shell Technology Ventures Leads $20 Million Investment in Minigrid Specialist Husk". www.greentechmedia.com. Retrieved 30 September 2021.
  14. "Project detail - HUSK POWER SYSTEMS, INC. - FMO". www.fmo.nl. Retrieved 30 September 2021.
  15. Staff. "Powering Villages from Rice Husks Wins Business Plan Competition", UVA Today , 6 May 2008. Retrieved 12 January 2011.
  16. 1 2 Nerenberg, Jenara."Husk Power Systems Wants to Lead 'a Revolution in Electricity'", Fast Company (magazine) , 5 January 2011. Retrieved 12 January 2011.
  17. Staff."Rice husk power to light up villages", The Hindu , 26 July 2010. Retrieved 12 January 2011.
  18. Nkosi, Mamsi (5 September 2023). "Husk Power launches "Africa Sunshot" initiative at Africa Climate Summit". IT News Africa | Business Technology, Telecoms and Startup News. Retrieved 14 September 2023.
  19. Kumar, Neeraj (5 September 2023). ""Africa Sunshot" initiative launched by Husk Power at the Africa Climate Summit, targeting 2,500 solar minigrids over 5 years to supercharge low-carbon economic growth in rural Sub-Saharan Africa". Husk Power Systems. Retrieved 14 September 2023.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.