Our path to a sustainable future lies in the adoption of renewable energies. Photovoltaics, wind energy, and biogas plants are at the forefront of this movement, significantly advancing the energy transition. Germany has made significant strides in integrating renewable energies across various sectors. According to the German Environment Agency's AGEE-Stat, renewable energy sources accounted for 51.8% of gross electricity consumption in 2023. Looking ahead, the German government aims for renewables to cover at least 80% of the country's electricity needs by 2030. This ambitious goal requires expanding plants, systems, and storage capacities. How this can work, what prerequisites are required and why options like pumped storage hydroelectricity plants, flexible biogas plants, large-scale batteries, and clean hydrogen storage are crucial for maintaining a reliable energy supply - find out all about it in our latest article: https://lnkd.in/eXgF-k42 #DEKRA #DEKRAsolutions #renewables #sustainability #climateneutral
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Reimagining Energy & Mobility | Consulting | Circular Economy | Creator | Helping College Students | Podcast Host
It will not only be Battery Energy Storage Systems (BESS), Solar Power Plants, wind energy, hydropower plants, thermal batteries, solar-powered hydrogen extraction, or natural thermal reservoirs alone that will help humanity ditch conventional energy resources that pollute our environment. It will be the balance of all these renewable energy resources that will lead us towards a sustainable future. In the short run, these renewable energy sources are most effective in reducing carbon emissions. However, in the long run, recycling them may prove to be a challenging task. #circulareconomy #bess #energy #renewables
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Power-to-Gas Market: Bridging Renewable Energy and Sustainable Fuel Solutions 🔗 Learn more:https://lnkd.in/gSwP3kBB The Power-to-Gas market represents a pivotal innovation in the transition to sustainable energy systems. By converting surplus renewable energy into hydrogen or methane, Power-to-Gas technology offers a versatile solution for energy storage and decarbonizing sectors like transportation and industry. This market is gaining momentum as countries strive to meet climate goals and integrate higher levels of renewable energy into their grids. With increasing investments and advancements in electrolysis and methanation technologies, the Power-to-Gas market is set to play a crucial role in achieving a carbon-neutral future. #PowerToGas #RenewableEnergy #SustainableFuel #EnergyStorage #HydrogenEconomy #Decarbonization #ClimateAction #MarketGrowth #GreenEnergy
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Principal Consultant to the Govt | Bioethanol | BioGas| Petroleum Refinery Products | Decarbonization | Energy Transition| Green Hydrogen | Public Policy|Ex-ONGC | NIT W | IMT Ghzb | IIT B
Sharing key insights from the recent IEA webinar on renewable energy! 🌍💡 Discussed groundbreaking advancements in solar, wind, green hydrogen, biogas, and more. 🌞🍃 Thrilled about the forecasted growth, paving the way for a sustainable future. #RenewableEnergy #IEAWebinar #SustainableFuture
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Who is leading #renewables #energy in 2024? Here's a closer look at the global race to #renewableenergy. Discover the diverse landscape of renewable energy adoption worldwide. From 🇨🇷Costa Rica's impressive 99.7% reliance on renewables to 🇨🇳 China's massive renewable capacity.
Who is leading in Renewable Energy in 2024
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#greenhydrogen #industrialClusters Guideline These guidelines provide recommendations in the preparation, implementation, and upscaling of green hydrogen industrial clusters for governments and industries As a key element of this programme, UNIDO has developed a three-phase model for establishing green hydrogen industrial clusters (GHIC)which defines industrial clusters that share green hydrogen and renewable energy for various purposes, including material production, heating and cooling, power balancing, local mobility, and industrial feedstock. The World Bank Ministry of Ports ,Shipping and Waterways. Government of India Asian Development Bank (ADB) UNIDO UNIDO Environment Renewable Energy World Renewable Watch Magazine Office of Energy Efficiency and Renewable Energy (EERE), U.S. Department of Energy Solar Is My Passion #windenergy #windpower #solarenergy #solarpower #solarpanels #renewablepower #renewableenergy #renewablefuture
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42% of grey hydrogen in the EU to be replaced by green by 2030. 60% by 2035. A reported six million tonnes per year by 2035. Back of an envelope that's: 35,000 - 38,000 MW of electrolysis capacity assuming a 60-65% electrolyser efficiency, that of leading alkaline, AEM and PEM electrolysers today. Compare that to Supercritical's 88% efficiency which requires 26,000 MW. That's 💧- 8,000 MW less electrolyser deployment and 💨 - 17,700 MW less wind capacity (assuming a 45% capacity factor) or ☀️ - 26,600 MW less solar capacity (assuming a 30% capacity factor) Efficiency saves cost and investment all through the value chain. Let's not forget that the largest operational electrolyser in Europe today is 20MW and it's been operational for a year and a half already and not been beaten! It's a tall order to be met, but I love to see the ambition. Let's do this!
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Southeast Asia’s green hydrogen build-out should be second to renewables: Renewable energy deployment should be prioritised over green hydrogen development in Southeast Asia but hydrogen should be reserved for “no-regret” hard-to-abate applications, according to a new report by Agora. #hydrogen #HydrogenNow #H2View
Southeast Asia’s green hydrogen build-out should be second to renewables
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Storage is a challenge with liquid form requiring massive refrigeration infrastructure and gaseous form occupying large volumes.
Green hydrogen is produced through a process called electrolysis using renewable energy sources, such as wind, solar, or hydropower. It is considered "green" because the production process generates no direct greenhouse gas emissions, making it an environmentally friendly and sustainable source of hydrogen. Process: 1. Green hydrogen production relies on electricity generated from renewable energy sources. This can include electricity from wind turbines, solar panels, or hydropower plants. 2. The electricity generated from renewable sources will be used to power the electrolyser. 3. In the electrolysis process, water (H2O) is split into its constituent elements, hydrogen (H2) and oxygen (O2). The electrolyser operates by passing an electric current through water, causing hydrogen gas to be released at the cathode and oxygen gas at the anode. 4. The green hydrogen will be now stored and distributed to different industries and sectors. 5. Green hydrogen has a wide range of end uses across various sectors. It can be used for residential and industrial heating and cooling applications. #hydrogeneconomy #hydrogen #greenenergy #renewableenergy #cleanenergy #energytransition #gogreen #energyfuture #solarenergy #windenergy #greenhydrogen #greenammonia #greenfuture #hydrogentechnology #greencommunity #energyefficiency
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Embrace Renewable Energy Today! Renewable energy presents a viable path forward to diversify its energy mix and enhance energy security. In today’s world, the shift towards renewable energy is not just a choice but a necessity. As Zambia currently faces long power cuts due to low water levels, could other renewable energy sources such as solar, wind and biomass offer immense potential to reshape our energy landscape while mitigating climate change impacts. #renewableenergy #forasustainablefuture #launcherengineers
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𝐏𝐨𝐥𝐢𝐜𝐢𝐞𝐬 𝐟𝐨𝐫 #𝟑𝐱𝐑𝐞𝐧𝐞𝐰𝐚𝐛𝐥𝐞𝐬 Not only green hydrogen production generates socio-economic benefits in developing countries, it also helps stabilise power grids, allowing more renewables integration in the power system, which supports countries reach #3xRenewables by 2030. Learn about the crucial role of policy priorities for green hydrogen production & applications.👇 https://lnkd.in/gEufbVdh
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