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Old Toronto, Canada
11-50 Employees
We are Disruptors and Innovators in the space of Plastic Waste Diversion and Hydrogen Production. FusionOne’s HydroPlas™ reactor offers a solution to tackle both these problems. FusionOne™ produces a Synthesis gas with very high Hydrogen content perfect for generating many Megawatts of Zero Emission energy or clean Hydrogen road fuel. FusionOne™ will be using a proprietary technology where Hydrogen will be separated from the SynGas produced in its HydroPlas™ system. Our HydroPlas™ System is the next generation in Thermal Decomposition Technology producing green Hydrogen from Plastic Waste. Various sustainable commercial products are produced as outputs including fuel cell grade pure Hydrogen and Zero Emission electricity. Modularity Our system can be adapted to suit the output products with the highest green return. Zero Emission Nothing, nada, zero is released, nothing is wasted, producing fossil free power.
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Featured
Plastic Waste to Hydrogen Energy
... Plastic Waste to Hydrogen Energy. FusionOne diverts plastic waste from landfill converting it to Hydrogen and Electricity, Creating the zero emission future we all deserve. Our HydroPlas™ System is the next generation in thermal decomposition technology producing green hydrogen from plastic ...
Brisbane City, Australia
1-10 Employees
2019
Viridius Energy will be pausing the project due to various commitments.
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Featured
TECHNOLOGY | Viridius Energy | Plastic Waste to Hydrogen
... TECHNOLOGY | Viridius Energy | Plastic Waste to Hydrogen ...
Grevenmacher, Luxembourg
Our mission is to turn local non-recyclable waste into a clean driver of local energy security and reduced infrastructure stress – while improving air quality, environment, and carbon footprint. Having successfully co-founded, built and sold a first industrial cleantech start-up to Siemens AG, and then a second one to Nalco; Jan Grimbrandt founded Boson Energy in 2008, together with long-time business partner Professor Wlodzimierz Blasiak. The company was founded on research that Prof Blasiak started already in the 80s, with the vision to produce local hydrogen directly from biomass and waste. Peter is a former technical director of Mälarenergi, with 40 years of experience in Swedish waste to energy. Peter has studied chemistry and engineering chemistry at Västerås University and process production and process engineering at Mälardalen University. Bengt is a Swedish waste contractor and investor with 40 years of experience in waste management, recycling and trade. Staffan is a serial technology entrepreneur that has been instrumental in taking six companies to IPO. Richard has 40 years of experience managing businesses JVs, R&D, manufacturing, sales & marketing, corporate & business level strategy at Goodyear and then Shell.
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Featured
Sector coupling defined: Waste-to-Hydrogen-to-X
... Sector coupling defined: Waste-to-Hydrogen-to- ...
Gold Coast City, Australia
11-50 Employees
2019
With our head office located on the Gold Coast, Queensland, Australia, Green H2 4U Pty Ltd is an Australian registered company within the H2 4U Pty Ltd group. We specialise in High Temperature Waste Gasification (HTGW) Plants that convert almost 100% of waste materials into energy and valuable by-products utilising our proven technology. Our Mission is to provide a two-fold solution to de-carbonize the world by reducing toxic waste & producing green hydrogen in a safe, environmentally sound & competitive means, using the process of gasification to become a world leader in green energy supply. Our vision is to continuously challenge ourselves to understand the evolution of green energy, while offering market leading solutions domestically & globally to safely produce Green Energy as world leader in clean energy supply. Our unique design and technology for High Temperature Waste Gasification has reached a maturity level where we can roll it out with confidence.
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Proven Waste-to-Green Hydrogen Technology
... Proven Waste-to-Green Hydrogen ...
Thousand Oaks, United States
2017
We are proud and committed champions of people whose voices have been traditionally silenced including the LGBTQIA+ communities, gender diverse identities, BIPOC (Black, Indigenous, and People of Color), people with disabilities, women, refugees and immigrants, among others. We are presently working on developing green hydrogen and carbon capture and utilization technologies.”. We are experiencing warming at a rate unprecedented in the history of civilization. We are addressing the problem of global warming at different scales. We are focused at the outset on green hydrogen production in order to decarbonize hydrogen production. Founded in 2017 the company continues working towards developing and implementing technology to covert biowaste products into needed products, such as biochar and green hydrogen. Our aim is to produce products that have that most impact towards saving the planet. We believe in transparency and accountability by our leadership.
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Hago Energetics – For An Abundant Future
... Turning waste to hydrogen since ...
Riga, Latvia
11-50 Employees
2019
ETGAS produces clean, renewable and low-cost gas containing the H2 and CO molecules – needed building blocks for a smooth transition of industries to true net zero. We offer energy-intensive companies a path to carbon negative Scope 1 emissions by switching to our supplied renewable gas, with carbon capture prior gas combustion as option.
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Renewable gas supply | ETGAS
... ETGAS builds-owns-operates waste gasification plants that convert non-recyclable waste to hydrogen rich renewable synthetic gas - a substitute of natural gas in various industrial processes. ...
Dhahran, Saudi Arabia
11-50 Employees
2012
Our $1.5 billion Sustainability fund supports Aramco’s ambitions to achieve net-zero Scope 1 and 2 greenhouse gas emissions across its wholly-owned operated assets by 2050, development of new lower-carbon fuels businesses, and furthering Aramco’s broader environmental objectives. A $500 million fund focused on digital and industrial technologies that can add value to Aramco’s operations. A $1 billion fund investing in disruptive technologies and business models outside of the energy industry, to provide financial return and diversification opportunities for the company. The mission of our strategic venturing program – our sustainability and digital/industrial funds – is ‘to invest globally into start-up and high growth companies with technologies of strategic importance to Aramco, to accelerate their development and deployment in Aramco’s operations’. Our Prosperity7 program seeks to invest into highly scalable ventures, led by world-class management teams, with disruptive technologies and business models, outside of the energy sector.
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Waste gases to hydrogen
... Waste gases to hydrogen - Aramco ...
North Shore, Australia
1-10 Employees
This is a great space to write a long text about your company and your services. Talk about your team and what services you provide. Clean Energy Resources Pty Ltd (CER) has brought together leading-edge technology, putting a value on waste, converting all manner of municipal waste into green hydrogen, clean baseload energy, and valuable renewable resources. We do all of this without creating emissions as all by-products are reformed into value-added materials. A different approach, using a new method of manufacturing.
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Waste to Green Hydrogen | Clean Energy Resources Australia
... Waste to Green Hydrogen | Clean Energy Resources ...
Gordonville, United States
1-10 Employees
At GenHydro™ we are all about innovation in the hydrogen industry. Our mission is to produce low-cost emissions-free hydrogen, enabling a multiple industry transition to clean energy and production. At GenHydro™ our goal is to be a part of the global transition to emissions-free energy. Our goal is not to be a disruptor to these workers and their communities, but to be a partner in helping their communities flourish, and ensuring that as the world transitions to clean energy, lives and livelihoods remain uninterrupted. The GenHydro system utilizes waste metals like aluminum, to separate hydrogen from H2O and also cogenerate thermal and electrical energy. Fundamentally what GenHydro does is waste to hydrogen + energy. Our focus is utilizing a reaction-based method for hydrogen production, with the goal of high yield at a groundbreaking low cost. What this means for us is using our technology to provide a means for existing industries to keep doing what they do best, while also moving towards emissions-free production.
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Waste to Hydrogen + Energy
... Waste to Hydrogen + ...
Cranage, United Kingdom
11-50 Employees
We are ISO 9001 accredited and members of MAKE. Today we offer the highest quality of fabrications available on the market. Since 1934, we have provided superior service to our customers and have assisted them in achieving their goals. Our expert teams can provide the design & manufacture of pressure vessels, pipework, tankage, coils, and heat exchangers to a wide range of codes and standards. Our team of experts are happy to answer any questions or enquiries you have.
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Products - Pressure Vessels, Coils, Pipework and more — W.H. Capper (UK) Ltd
... Capper (UK) Ltd, manufacturers of fusion welded fabricated products since 1934, for a range of industries including waste to energy, hydrogen, oil & gas, power generation, chemical and petrochemical. ...
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Some interesting numbers and facts about the results you have just received for Waste-to-Hydrogen
| Country with most fitting companies | Australia |
| Amount of fitting manufacturers | 9 |
| Amount of suitable service providers | 6 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 2012 |
| Youngest suiting company | 2019 |
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Waste-to-Hydrogen refers to a set of innovative processes designed to produce hydrogen fuel from organic and inorganic waste materials. This technology harnesses chemical reactions, such as gasification and pyrolysis, to break down waste products, including plastics, biomass, and municipal solid waste, into hydrogen gas, alongside other byproducts. The appeal of waste-to-hydrogen technology lies in its dual potential to mitigate the global waste crisis and provide a sustainable, low-carbon alternative to fossil fuels. By converting waste that would otherwise end up in landfills or incinerators into a valuable energy source, this approach significantly reduces the environmental footprint associated with waste disposal and energy production. Moreover, the hydrogen produced can be utilized in various applications, from fueling vehicles to generating electricity, presenting a versatile solution to the growing demand for clean energy. The role of waste-to-hydrogen in advancing the circular economy and promoting environmental sustainability is increasingly recognized, positioning it as a pivotal technology in the transition towards a more sustainable and energy-efficient future. Through its contribution to waste reduction and clean energy production, waste-to-hydrogen technology embodies a promising avenue for addressing some of the most pressing environmental and energy challenges of the 21st century.
1. Reduction of Landfill Waste
Waste-to-hydrogen technology significantly decreases the volume of waste that ends up in landfills. By converting organic and inorganic waste into hydrogen, this innovative approach not only minimizes environmental pollution but also extends the lifespan of landfills.
2. Production of Clean Energy
One of the most compelling advantages of waste-to-hydrogen is its ability to produce clean, renewable energy. Hydrogen generated through this process can be used to power fuel cells in vehicles and electricity generators, producing only water vapor as a byproduct, thus drastically reducing greenhouse gas emissions.
3. Energy Security
By utilizing local waste materials to produce hydrogen, waste-to-hydrogen technology contributes to enhancing energy security. This method reduces reliance on imported fuels and fossil fuels, promoting a more sustainable and self-sufficient energy supply chain.
4. Economic Benefits
The adoption of waste-to-hydrogen technology can stimulate economic growth by creating jobs in the green energy sector. Furthermore, it offers a cost-effective solution for waste management, as the value derived from hydrogen production can offset the costs associated with waste disposal.
While evaluating the different suppliers make sure to check the following criteria:
1. Technology Efficiency
Ensure the supplier's technology can efficiently convert waste materials into hydrogen, maximizing output and minimizing waste.
2. Environmental Impact
Evaluate the environmental footprint of the technology, prioritizing suppliers that offer solutions with minimal emissions and sustainable processes.
3. Cost-Effectiveness
Consider the overall cost of the technology, including installation, operation, and maintenance, ensuring it aligns with budgetary constraints and offers competitive pricing.
4. Regulatory Compliance
Verify that the supplier's technology complies with all relevant local and international environmental regulations and standards.
5. Technical Support and Maintenance
Assess the level of technical support and maintenance services offered by the supplier, ensuring reliable operation and longevity of the system.
6. Proven Track Record
Look for suppliers with a proven track record of successful waste-to-hydrogen projects, demonstrating their capability and reliability in delivering effective solutions.
Waste-to-hydrogen technology is revolutionizing energy sustainability across multiple sectors. In the manufacturing industry, businesses are leveraging this technology to convert their production waste into hydrogen fuel. This not only significantly reduces the ecological footprint of manufacturing processes but also provides a renewable source of energy for operations, enhancing energy independence and lowering operational costs. In the realm of transportation and logistics, companies are adopting waste-to-hydrogen solutions to power their fleets. By using hydrogen fuel cells, businesses can operate vehicles with higher efficiency and minimal environmental impact. This application not only supports the shift towards green logistics but also helps in meeting stringent emission regulations. The agricultural sector presents another vital use case, where waste-to-hydrogen technology is utilized for managing agricultural waste. By converting organic waste into hydrogen, farms can generate clean energy for various applications, such as powering equipment or heating facilities. This approach not only aids in waste management but also contributes to the renewable energy portfolio of the agricultural industry. Lastly, waste management and recycling businesses are embracing waste-to-hydrogen technology to enhance their operations. By converting non-recyclable waste into hydrogen, these companies can generate an alternative revenue stream while contributing to the reduction of landfill waste. This innovative application underscores the potential of waste-to-hydrogen technology in driving circular economy initiatives across industries.
Waste-to-hydrogen technology, a promising innovation in renewable energy, currently stands at varying Technology Readiness Levels (TRLs), predominantly between 4 to 6, depending on the specific process involved. At these levels, the technology has moved beyond initial theoretical development and lab-scale testing (TRL 1-3) to small-scale process validation in controlled environments (TRL 4-6). This positioning is primarily due to several technical challenges that still need addressing for widespread commercial adoption. Key among these hurdles are the optimization of the gasification process to increase hydrogen yield, the development of more efficient and less costly catalysts, and the creation of robust systems capable of handling diverse waste streams without pre-treatment. Additionally, while pilot projects have demonstrated the feasibility of converting waste to hydrogen, scaling these operations to industrial levels introduces complexities in maintaining system efficiency and managing by-products sustainably. The energy balance of the processes, ensuring that more energy is produced than consumed, especially in terms of the overall carbon footprint, remains a focal area of research. Despite these challenges, the incremental progress within each TRL showcases a clear pathway toward optimizing this technology for commercial viability, highlighting the ongoing commitment to overcoming technical barriers and advancing waste-to-hydrogen as a sustainable energy solution.
In the Short-Term, waste-to-hydrogen technology is expected to see significant improvements in efficiency and cost-effectiveness. Innovations such as enhanced catalytic processes and better waste pre-treatment methods are on the horizon. These advancements are aimed at increasing the hydrogen yield from various waste materials, including plastics and organic waste, making the technology more viable for smaller scale applications. Moving into the Mid-Term, the focus will likely shift towards scaling up these technologies to accommodate larger waste streams. Integration with existing waste management systems will become a key area of development, alongside the exploration of more diverse waste inputs. This phase may also witness the emergence of modular waste-to-hydrogen systems designed for easy deployment in urban areas, further reducing the carbon footprint associated with waste transportation. In the Long-Term, the ambition is to achieve a closed-loop system where waste-to-hydrogen technology not only provides a sustainable source of hydrogen fuel but also plays a crucial role in waste management and reduction. Breakthroughs in artificial intelligence and machine learning could lead to autonomous waste sorting and processing systems, maximizing efficiency and hydrogen production. Additionally, the integration of carbon capture and storage technologies could render waste-to-hydrogen processes carbon-negative, contributing significantly to global decarbonization efforts.
Some interesting questions that has been asked about the results you have just received for Waste-to-Hydrogen
What are related technologies to Waste-to-Hydrogen?
Based on our calculations related technologies to Waste-to-Hydrogen are Water/Ocean Cleaning Technologies, Waste Management, Renewable Energy, Sustainable Fashion, Smart Grid
Which industries are mostly working on Waste-to-Hydrogen?
The most represented industries which are working in Waste-to-Hydrogen are Energy, Financial Services, Manufacturing, Sustainability, Administrative Services
How does ensun find these Waste-to-Hydrogen Companies?
ensun uses an advanced search and ranking system capable of sifting through millions of companies and hundreds of millions of products and services to identify suitable matches. This is achieved by leveraging cutting-edge technologies, including Artificial Intelligence.
