Solar Richmond
About Solar Richmond
The firm aims to promote and inspire the use of solar power and energy efficiency in order to bring the economic benefits of the green economy to Richmond. The company serve the community through solar installation training, educating a new "green-collar" workfor
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Expert Collections containing Solar Richmond
Expert Collections are analyst-curated lists that highlight the companies you need to know in the most important technology spaces.
Solar Richmond is included in 1 Expert Collection, including Renewable Energy.
Renewable Energy
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This collection contains upstream and downstream solar companies, as well as those who manufacture and sell products that are powered by solar technology.
Latest Solar Richmond News
Jun 21, 2015
Sunday, Jun 21, 2015 2:00 PM UTC The energy revolution that has 1 percenters shaking in their boots Director Shalini Kantayya talks to Salon about the incredible potential of solar power 0 All Share Services (Credit: Catching the Sun ) When you hear about Richmond, California — on the environmental beat, at least — it’s usually in the context of the Chevron oil refinery, one of the country’s biggest, that casts its long shadow over the city. There was the fire and explosion in 2012 that sent toxic fumes into the surrounding Bay Area. There are the continuing worries about the long-term health effects facing the people who breathed those fumes in. There’s the everyday air pollution , and the everyday risk, that comes from living in the refinery’s vicinity and, more quietly, there’s the big money Chevron pumps into local elections to ensure none of this is examined too closely. “The only time you ever saw Richmond on the news was two things: somebody’s bleeding or somebody’s burning,” Michele McGeoy, the founder of Solar Richmond , tells a class of job trainees at the beginning of the documentary “ Catching the Sun .” “I want to create some good news in Richmond.” The project in Richmond, and in cities like it across the country, is to shift from what environmental activist Van Jones, who also features prominently in the film, calls a “pollution-based economy,” filled with haves and have-nots, to an economy based on green energy — the environmental benefits of which are almost second to the creation of jobs, and the improved quality of life, that investment in solar innovation can create. The film follows the stories of the workers, entrepreneurs and political activists who are working to make that happen, and of the forces, both local and global, that can help or hinder the process. Salon spoke with Shalini Kantayya, the film’s director, about America’s place in the global clean energy race. Our conversation has been lightly edited for length and clarity. “Catching the Sun” starts out a little differently from most environmental films: You don’t really talk about the planet, large-scale, or climate change, but go straight to these very local impact of fossil fuels, focusing on one community where people might not normally prioritize environmental issues. Could you tell me a little bit more about why you chose that approach? I was very interested in Richmond, California, as a symbol of other American cities. It was a large industrial city, and a lot of those industries have left Richmond, leaving it with high amounts of unemployment. Also, a lot of those industries had been dirty industries, so it had higher rates of cancer and asthma. When I discovered this Solar Richmond training program, I thought it could be a symbol of the type of transformation that could be good for cities across the country. That’s sort of what put me on this journey, and I started to tell a small story about American workers seeking to retool for jobs in the solar industry. After a year or two of wondering why they haven’t gotten jobs, I started to unravel the large global forces at play deciding whether American workers get jobs in the industries of tomorrow. That journey took me to China. Integrating those two stories — that local story in Richmond and this global story in China — that took two years in the edit room. It’s so disheartening in the second half of the film when this character who’s gone through the training program, and is now a skilled worker, just can’t find a job in solar. What are some of the global forces that you found that were working against him? What I really began to understand in the making of this film is the importance of public policy in creating common good for us, as a democracy. I think we’ve been so swayed by media to believe that anything that is in the common good is communist. But actually our environment is something that is in our common good. And so, what I came to understand is that we can use the power of public policy to avert a crisis. Here in the United States we have a history of doing that — Ronald Reagan signed the Montreal Protocol. We know how to do that, and that’s what I got excited about in the making of this film. And the fact that, because we’re dealing with electricity, a lot of those decisions get made at the local and the state level, where people have a lot of power. With Congress totally missing in action, we can make this change all across the country. You Might Also Like Can you talk a little bit about how public policy toward renewable energy in the U.S. differs from what’s going on in China? I think the foremost distinction is that the government of China accepts the signs of global warming and accepts the signs that human beings are causing it. And also, China has passed aggressive national policy to become a world leader in renewable energy technology. In two of its last five-year plans, it’s identified renewable energy as a major sector of growth in China. What we’ve seen with that very aggressive policy is, China went from producing a fraction of 1 percent of the world’s global solar to producing 90 percent of the world’s global solar. That happened essentially in just over five years. What’s interesting about China’s entry into renewable energy is that it’s also helped to bring the price down. What’s happening is that the U.S. now has the opportunity to create jobs downstream, in the installation, in the design and the engineering, where there are more jobs anyway — and those jobs cannot be outsourced. I really think the U.S. and China can work together to solve this crisis. At the local level, you suggest the problem isn’t even about getting people to accept climate change. There’s that really strong moment in the beginning of the film where a couple is speaking at home. The husband says, “We can get solar panels on our roof. It can lower the electricity bill.” And the wife is telling him to “be practical” — she’s not believing it could happen. It seems like there’s still a lot of skepticism in the U.S. that this industry is capable of growing as much as it is projected to. Absolutely, and here’s the thing: You don’t have to accept what 99 percent of the world’s scientists agree upon. You don’t have to actually believe in climate change to believe that solar energy is good for our country. I think that’s the big distinction that my film makes. It shows that in so many places across the country, it is the same cost or cheaper — rapidly becoming cheaper — than the cost of fossil fuels. And with fossil fuels, there are all these expenses that we don’t factor in to the cost of energy: say, for instance, pollution, and the effect that fossil fuels have on our air and the amount of asthma and the cost of sending our kids to the hospital for those inhalers. We don’t factor that into the cost of fossil fuels, nor do we factor the other costs that we spend: our human lives, our resources, our military. Once you begin to factor in those external costs, solar wins economically every day of the week and twice on Sunday. I’m wondering, would you argue that taking climate change out of the renewable energy conversation altogether could be a way of depoliticizing it and moving forward? Absolutely. I think one of the strongest things about the film is that we feature someone like Debbie Dooley, a Tea Party activist. Libertarians and Tea Party activists love solar because this is about a free market for energy, which we don’t have — we have a monopoly. Most of us get a bill from our utility company, and whatever they charge us, we have to pay. So there are lots of people on the left and on the right together who just want clean energy choices and consumer choices around energy. We want to break up these monopolies that we don’t need anymore around energy. We need to innovate around energy, and this is about being competitive in the technologies of the future. When you think about something like solar, it’s renewable. Once you have it up, there’s no marginal cost. For so many places, it really makes sense. It is our job in the United States, as a government, to create the conditions to make us competitive in the next century, to make us competitive and innovative, which has always been the strength of the United States in the industries of tomorrow. Just like China, we should be doing this for national security reasons, we should be doing this for economic reasons and job reasons, and for the health of our communities. What do we do about the opposition coming from utilities and from fossil fuel? The way the film treats Van Jones’ dismissal from the White House heavily implies that he was attacked by people who didn’t support the green energy agenda — how formidable of a threat do you see that as being? Well, look. The fossil fuel industry consolidated wealth and power in the hands of very few people. That’s how we got the Koch brothers, that’s how we got the Saudi royal family, that’s how we got the 1 percent and so many problems of our democracy as a result of their wealth and power and influence and interference in our democratic process. I think the big exciting idea about solar energy is that it’s good for the 99 percent. When you have the right policy, like they did in Germany, you can put solar on your house, and you become an independent power generator. Instead of your utility sending you a bill, they’re sending you a check. You can imagine that the utility companies, they don’t want to do this! I mean industrialists were almost left out of the solar revolution in Germany: 80 percent of the people that benefited were ordinary citizens like you and me who became power generators. It’s good for our middle class, it democratizes energy, it decentralizes energy, it makes it more sacred. It has utility companies and 1-percenters who have benefited from dirty fossil fuels shaking in their boots, and with good reason. It’s economically competitive. I think we’re going to have a battle, and some of that is just around public education and making sure we get across the facts. Are you optimistic that the U.S. will be able to build an economy like Germany’s — its own version of the clean energy economy? In all honesty, my concern is that it will be big businesses that go solar. We’ll have big industrial solar, and it’ll be less every person becoming an independent power generator. But that really depends on the levers of public policy. Here’s what’s exciting: With Congress missing in action, at least 29 states have made commitments to being at least 10 percent renewable by 2020. States like California are leading the way — it’s already running on 25 percent renewable energy, and quickly moving to 33 percent. That’s happening on the state level. Here in Los Angeles, we’re moving to 20 percent by 2020, or making headway to set those targets. I think this should be a race to the top. We should be outcompeting each other state by state to see who is going to be the most renewable state in the country. The more that we do that, and we get our mayors and our governors and our state representatives … and this isn’t the Congress! Your city council might have three friends from your high school on it that you know. We can make change at this level. This is tangible. But the democratization of our energy is going to require citizens to take action, that we go to our city councils and we go to our state leaders, and we say yes, we want clean energy choice. We want to be competitive in the industries of the future. We don’t want to miss the next opportunity, because the world already understands this. Most of the new energy that’s coming online in the world is already renewable. The world is going to be mostly renewable by 2030, so the only question is what country is going to get the biggest piece of that multi-trillion-dollar industry. I really do believe that everything we love can be saved: our democracy, the middle class, the polar bears. But it’s going to be like a third industrial revolution. It’s going to take that kind of setting of targets and using the levers of public policy, which are the tools we have as a democracy. Lindsay Abrams is a staff writer at Salon, reporting on all things sustainable. Follow her on Twitter @readingirl, email labrams@salon.com.
Solar Richmond Frequently Asked Questions (FAQ)
Where is Solar Richmond's headquarters?
Solar Richmond's headquarters is located at Richmond.
Who are Solar Richmond's competitors?
Competitors of Solar Richmond include Bossa Nova Vision, NEI Corporation, Clean Power Finance, Sopogy, Nanosolar and 12 more.
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- See competitors' playbooks
- Stalk the smart money
- Identify tomorrow's challengers
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Compare Solar Richmond to Competitors
Octillion Corp., together with its wholly owned subsidiaries, is a technology incubator focused on the identification, acquisition, development, and commercialization of alternative and renewable energy technologies. Through established relationships with universities, research institutions, government agencies and start-up companies, the company strive to identify technologies and business opportunities on an edge of innovation that have the potential of serving and unmet market needs. nOnce a technology has been identified, the company fund the research and development activities relating to the technology with the intention of ultimately, if warranted, licensing, commercializing and marketing the subject technology, either through internal resources, collaborative agreements or otherwise. Unique to the company's business model is the use of established research infrastructure owned by the various organizations the company deal with, saving us capital which would otherwise be required for such things as land and building acquisition, equipment and furniture purchases, and other incidental start up costs. As a result, the company are able to conduct research in development. nnAmong the company's current research and development activities is the development of a patent-pending technology that could adapt existing home and office glass windows into ones capable of generating electricity from solar energy without losing transparency or requiring major changes in manufacturing infrastructure. The company are also developing a system to harness the kinetic energy of vehicles in motion as part of a broader effort to enhance the sustainability and energy efficiency of transportation infrastructures and systems.
Atas has compiled green building information regarding Cool Metal Roofing, Transpired Solar Collector panels and various means of credits from the federal government, as well as possible state credits and incentives from various companies.
NEI Corporation is a Somerset, NJ based company that has received a grant(s) from the Department of Energy's SBIR/STTR program. The abstract(s) for these grant award(s) are provided as well since they provide insights into NEI Corporation's business and areas of expertise. This project will develop a mercury remediation solution for use in contaminated U. S. Department of Energy waste sites, thereby leading to cost savings and reducing the time for treating waste. This project will develop a nanoparticle-based technology that will enable coal-fired power plants to use sources of water other than conventional rivers or lakes. The nanoparticle-based technology also will be a cost-effective means of reducing the amount of toxic metals in waste water streams. This project will develop a nanotechnology-based coating for industrial vapor-to-liquid heat exchangers to enhance their performance by an order of magnitude and improve the energy efficiency of associated industrial processes. This project will enhance the properties of elastomeric seals for use in geothermal energy production and has the potential to prevent failure of equipment and to allow the down-hole equipment to run unattended for extended periods of time, greater than 5 to 10 years, without maintenance. This project will develop nanoparticle-enabled fluid technology to enhance the performance of heat exchangers used in small refining operations across the nation. The enhanced performance of the heat exchangers will lead to cost and energy savings. This project will develop technology to enable a new generation of lithium-ion batteries to deliver the required energy storage capacity at an economical price, making Li-ion batteries for electric utility and vehicles applications more affordable. This project will develop non-chromate corrosion inhibiting coating systems to enable the use of light weight magnesium alloys in automobiles. The result will lead to a reduction in greenhouse gas emissions and fuel costs to consumers. This project will develop a nanotechnology-based, self-healing industrial coating. Self-healing coatings will have significantly enhanced operational lives, thereby reducing installation and repair costs. There is a present need for sorbent technologies to enable coal-fired power plants to reduce mercury emissions. This project will develop a novel environmentally friendly sorbent technology to meet this emerging market need. This project will develop and implement a new class of 5V high voltage Li-ion battery cathode material for next generation plug in hybrid electric vehicles (PHEVs). This project will develop advanced materials for use as the internal wall of a fusion power reactor is expected to enable fusion power to be developed as a sustainable source of energy. This project will develop a new chemistry for Flow Batteries so that it is highly efficient, has long cycle life, and is low cost and non-toxic. The flow batteries can be used by utilities, in conjunction with green power generation, such as solar, wind turbine and fuel cell. The proposed technology will reduce the cost of the mercury removal from coal fired power plants, thereby allowing power plant utility companies to comply with mercury regulation. The proposed novel modified dielectric percolative composites will be reliable and will have high dielectric constant, thereby delivering high energy density to future solid state pulsed power systems.
Solarno is a company that received a STTR Phase I grant for a project entitled: Synthesis of multifunctional nanofibrous polyaniline/carbon composites. Their their award is funded under the American Recovery and Reinvestment Act of 2009 and their project will develop novel multifunctional materials based on polyaniline (PAni) nanofibers (PANFs) and carbon nanofibers(CNFs) for energy storage. Although PAni composites have been reported for a wide range of applications, including sensors, biosensors, photoelectrochromic cells, etc., due to their excellent electrical, thermal and mechanical properties, none capitalize on the enhanced properties expected from the combination of PANF with CNF. PANFs have greater electronic conductivity than PAni nanospheres and nanorods and can be synthesized on a variety of substrates. Solarno will use a proprietary process for synthesizing composites of PANFs on CNFs. In Phase I Solarno will use these composites as electrode materials for asymmetric supercapacitors, an enabling technology that provides both high energy and power, with the specific technical objectives of: synthesizing and characterizing PANFs on CNF substrates, and achieving supercapacitor performance of 15 Wh/kg, 10 kW/kg and >10 cycles, thus far exceeding current lead acid batteries in terms of power and cycle life. In Phase II we will improve the energy density of these devices to enable potential replacement of such batteries, and explore other functions for the composites, such as sensors and electro-chemical devices. The PANF/CNF composites developed by Solarno will be introduced to the supercapacitor market via materials sales, and partnering/licensing arrangements, and later to related electrochemical functions/applications. Solarno is targeting requirements of the Hybrid Electric Vehicle (HEV) market for its initial supercapacitor designs, and as such, the ultimate customers will be major automobile manufacturers. The market requires that capacitors provide higher energy density, reduced size, higher reliability, and lower cost. Commercially available EDLCs commonly provide energy densities around 4 Wh/kg, and power densities between 15-21 kW/kg. The supercapacitor developed here can excel in this market by providing energy density > 25 Wh/kg and better reliability (>2.0 x 104 cycles); the Phase I work will optimize the properties of our PANF/CNF composite to meet this goal. The supercapacitors will also be well-suited for load-leveling for renewable energy sources; direct societal benefits will come from improving the viability of HEVs and renewable sources, tied to reductions in fossil fuel consumption, providing bridge power for wind and solar power farms, and partially replacing lead acid storage batteries. The results of this work in optimizing PAni composites for supercapacitors will translate well into improved functionality for other applications.
Isosceles is a company that received a STTR Phase I grant for a project entitled: Full Spectrum Conjugated Polymers for Highly Efficient Organic Photovoltaics. Their their award is funded under the American Recovery and Reinvestment Act of 2009 and their project will demonstrate the feasibility of forming full spectrum highly efficient polymer solar cells from newly designed conjugated and potentially variable bandgap polymers that harvest visible through infrared light. The novel materials will be forged by incorporating Silole and donor-acceptor-donor moieties into the backbone and are expected to increase light harvesting and carrier mobility, and hence short circuit current output potentially by a factor of three over the state of the art. The key innovations of this work will also optimize energy levels to reduce voltage loss and further optimization of device structure and film morphology is expected improve fill factor. The primary objective of phase I is to determine the feasibility of forging full spectrum and high carrier mobility conjugated polymers that achieve highly efficient solar conversion. An ancillary goal of this work is arrive at an understanding of photophysical processes and device physics that will lead to optimal device fabrication during phase II. The environmental, societal and economic impacts of this technology are enormously broad. The ensuing abrupt drop in energy costs stemming from full spectrum harvesting promises to deliver stability and urgently needed relief to today's volatile oil based global economy. While photovoltaic (PV) production is already the fastest growing source of energy across the globe, the planned efforts of this STTR project are expected to disruptively reduce the projected cost of photovoltaic production in 2010 by a factor of 3. At a forecasted production cost of $0.70 per Watt, this research will demonstrate a technology that is competitive with the cost of electricity that is produced from fossil fuels. This technology will provide clean and cost competitive energy for home and industrial power, vehicle propulsion, consumer electronics, remote sensing, security, and an endless list of existing applications that currently rely on energy from fossil fuel.
The SolarWall heating and ventilation system aims to deliver one of energy ROIs possible in the commercial and industrial sector. The all-metal solar system is building integrated and heats the ventilation air that is required in commercial and industrial buildings using a perforated plate or transpired collector. Conserval Engineering invented this technology, which was subsequently branded as "SolarWall", and it has single-handedly set the standard for the global solar air heating sector because of its high efficiency and low cost. It is also a source of greenhouse gas reductions, with each 5m2 (53 ft2) displacing 1 ton of CO2 each and every year. The SolarWall technology has received commendation from both the US and the Canadian Government, with the US Department of Energy referring to it as "the most reliable, best performing, and lowest cost solar heating system for commercial and industrial buildings available on the market today". As well, the technology qualifies for up to 6 LEED points.
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