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Blockchain Is More Than Just Bitcoin: Surprising Uses in 2024
Introduction: The Expanding Horizons of Blockchain Technology. In recent years, blockchain technology has captivated the world’s imagination far beyond its cryptocurrency roots. While Bitcoin might have introduced the masses to blockchain, the potential applications of this technology stretch across various industries, reshaping how we approach security, transparency, and efficiency. In 2024, blockchain is proving itself in arenas few had anticipated, offering innovative solutions to age-old problems and opening new avenues for data management. Read to Continue...
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The Future of Energy: How Decentralization is Reshaping Power
Decentralized Energy System Market is projected to achieve a value of USD 12,443.6 million in 2023, with a linear behavior in the market growth it is forecasted to achieve a value of USD 21,377.6 million by 2033 with a CAGR of 12.5% during the forecast period 2023-2033.
The report presents an in-depth assessment of the ‘Decentralized Energy System Market’. This includes enabling technologies, key trends, market drivers, challenges, standardization, regulatory landscape, deployment models, competitive analysis, operator case studies, opportunities, future trends, value chains, ecosystem player profiles, and strategies included. The report also presents a SWOT analysis and forecast for Decentralized Energy System investments from 2024 to 2033.
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Top Companies in the Decentralized Energy System Market:
ABB Ltd
Siemens
Schneider Electric
General Electric
Honeywell
Tesla
Sonnenbatterie
LG Chem
Panasonic
BYD
Enphase Energy
Global Decentralized Energy System Market Segments:
By Type
Wind Power
Hydropower
Solar Power
CHP and Other Thermal Power Stations
Bioenergy
Geothermal Energy
Others
By Application
Industries
Commercial Areas
Large Buildings
Residential
Municipalities
Others
By End-user
Utility Providers
Independent Power Producers
Microgrid Operators
Others
Decentralized Power Generation Market Share:
The decentralized power generation industry's major players are making large investments in R&D to broaden their product offerings, introduce new goods, sign contracts, buy out businesses, increase their investment levels, and collaborate with other organizations to expand internationally.
Frequently Asked Questions:
Asia Pacific Decentralized energy system market value?
Which are the upcoming countries within the Europe Decentralized energy system market?
Which are the top 3 companies in Decentralized energy system market?
What is the cost of Decentralized Energy System?
Regional Analysis for Decentralized Energy System Market:
For a comprehensive understanding of market dynamics, the global Decentralized Energy System market is analysed across key geographies namely North America, Europe, China, Japan, Southeast Asia, India, Central & South America. Each of these regions is analyzed based on market research findings for the key countries in the region for a macro-level understanding of the market.
Important sections of the TOC
Economic Impact Variables on Decentralized Energy System Market: Illuminates the consequences of environmental, political and economic fluctuations, and explains changes in customer and consumer requirements. We also provide a detailed report of Decentralized Energy System on the technology risks and advancements in the global market.
Forecasts based on macro- and micro-economy: ensuring price, revenue and volume EV charging service forecasts for the market. It also includes, in addition to forecasting growth, revenue and import volume for the region, with revenue forecasting for the Decentralized Energy System application, along with revenue forecasting by cost, revenue and type.
Marketing Strategy Analysis: In this section, Decentralized Energy System analysis aims at niche positioning and provides information regarding target audience, new strategies and pricing strategies. We provide a comprehensive Decentralized Energy System marketing station analysis that investigates the problem. Marketing channel development trends, direct marketing as well as indirect marketing.
Business Intelligence: The Decentralized Energy System companies studied in this section are also assessed by key business, gross margin, price, sales, revenue, product category, applications and specifications, Decentralized Energy System competitors, and manufacturing base.
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The report can be used by investors and acquirers as part of their due diligence process when considering investing in or acquiring a technology company. These reports can provide valuable information on the company's financials, technology, market position, and other key factors.
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Fuel Cell Generator Market Is Driven by Minimalization of Carbon Residues
The size of the fuel cell generator market was USD 330 million in 2022, and the figure is set to rise at a CAGR of 17.50% from 2022 to 2030 and reach USD 1,199 million by the end of this decade.
There are several reasons for this development, including the minimalization of CO2 emissions, the easy availability of fuel cells, and their ability to renew energy. The snowballing need for the production of clean power along with minimal releases from CO2 will drive the market.
Numerous regions and nations throughout the globe are targeting to decrease overall releases of CO2 to zero by 2050, To achieve CO2 neutrality. The government's focus has amplified on making a decarbonized civilization in the past few years. To achieve this aim, the introduction of renewable sources, including solar, biomass, hydro, wind, and geothermal, is vital.
The production of electricity with the support of solar and wind has a few drawbacks, like the lack of ability to regulate the generation and huge quantity of output disparities reliant on weather conditions.
Aquaculture is the fastest-rising end-user developing at a CAGR of approximately 19.2%, credited to the increasing quantity of aquaculture amenities and increasing ecological impacts related to it such as the consumption of electricity and water. Mainly to lessen the environmental effects, governments have taken numerous steps to utilize fuel cell-based generators as an alternative to diesel generators.
North America is dominating the fuel cell generator market and is projected to continue with this dominance throughout the decade. This can be ascribed to the growing concentration and fast acceptance of clean sources.
In North America, the U.S. is leading the market, and it will develop with a CAGR of 18.1%, credited to solid economic support. The innovative growth in the usage of renewable sources and snowballing electricity needs from the aquaculture and data centers industry are the major reasons that will boost the industry in the future as well.
Hence, the minimalization of CO2 emissions, the easy availability of fuel cells, and their ability to renew energy are the major factors contributing to the growth of the fuel cell generator market.
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Distributed Energy Generation Market Business Trends,key Factors,Strategies and Huge Demand and opportunity by 2032
Market Overview: The Distributed Energy Generation (DEG) Market refers to the market for decentralized energy generation systems that produce electricity closer to the point of consumption. DEG systems include solar photovoltaic (PV) panels, wind turbines, small-scale gas turbines, fuel cells, and microgrids. These systems offer benefits such as increased energy efficiency, reduced transmission losses, enhanced grid resilience, and the potential for utilizing renewable energy sources.
The global distributed energy generation market size was valued at $246.4 billion in 2020, and is forecasted to reach $919.6 billion by 2030, growing at a CAGR of 14.2% from 2021 to 2030.
Here's an overview of the trends, scope, and demand in the Distributed Energy Generation (DEG) Market:
Trends:
Renewable Energy Dominance: Distributed energy generation is increasingly driven by renewable sources such as solar photovoltaic (PV), wind, and hydroelectric power. The transition towards cleaner energy sources is a prominent trend in the DEG market, supported by favorable policies and decreasing renewable energy costs.
Decentralization of Power Generation: The shift towards decentralized power generation is a significant trend. DEG systems allow energy to be generated closer to the point of consumption, reducing transmission losses and enhancing grid resilience.
Microgrids and Energy Resilience: The rise of microgrids, which are smaller-scale energy systems that can operate independently or in conjunction with the main grid, offers increased energy resilience during grid outages or disruptions. Microgrids, often powered by DEG sources, are gaining traction in both urban and remote areas.
Smart Technologies and IoT Integration: The integration of smart technologies and the Internet of Things (IoT) is transforming the DEG landscape. Smart meters, sensors, and advanced controls enable efficient energy management, real-time monitoring, and optimal utilization of distributed resources.
Energy Storage Integration: The combination of distributed energy generation with energy storage solutions, such as batteries, enhances the reliability and flexibility of DEG systems. Storage systems allow excess energy to be stored for later use, improving energy management and grid stability.
Scope:
Residential Sector: Distributed energy generation offers homeowners the opportunity to generate their own energy, reduce electricity bills, and potentially earn revenue by feeding excess energy back into the grid.
Commercial and Industrial Sectors: Businesses and industries can deploy DEG systems to reduce operational costs, enhance energy resilience, and demonstrate their commitment to sustainability.
Remote Areas and Off-Grid Solutions: DEG systems provide a viable solution for providing electricity to remote and off-grid areas where grid connection is challenging or uneconomical.
Microgrid Development: The scope of microgrids powered by distributed energy sources is expanding, catering to critical facilities, military bases, campuses, and communities seeking energy independence and resilience.
Demand:
Energy Security and Reliability: The need for reliable and secure energy supply is a fundamental driver for DEG adoption. Businesses and communities are increasingly valuing energy independence to mitigate the risks of grid outages and supply disruptions.
Environmental Sustainability: Growing awareness of environmental concerns is fueling demand for cleaner energy options. Distributed energy generation, particularly from renewable sources, aligns with sustainability goals and reduces carbon footprints.
Economic Benefits: DEG systems can offer significant long-term cost savings by reducing energy bills, avoiding peak demand charges, and potentially generating revenue through excess energy sales.
Energy Access in Remote Areas: The demand for electricity access in remote and underserved areas drives the adoption of DEG solutions, which can provide a reliable and cost-effective alternative to extending traditional grid infrastructure.
Grid Resilience and Disaster Preparedness: Microgrids and DEG systems gain demand from entities seeking improved resilience during natural disasters or grid failures, ensuring continuous energy supply for critical operations.
Regulatory Support and Incentives: Government incentives, subsidies, and policies that promote renewable energy and energy independence are significant demand drivers for DEG technologies.
The Distributed Energy Generation market is rapidly evolving to meet the demand for cleaner, more reliable, and decentralized energy solutions. Technological advancements, favorable policies, and changing consumer preferences are shaping the market's growth and expanding its scope across various sectors and regions.
Challenges: The distributed energy generation market also faces certain challenges, including:
Grid Integration and Regulatory Frameworks
Initial Costs and Financing
Grid Resilience and Stability
Overall, the distributed energy generation market offers substantial opportunities driven by energy security concerns, environmental sustainability goals, and the need for energy access. Overcoming challenges related to grid integration, financing, and grid stability will be critical to realizing the full potential of distributed energy generation and maximizing its benefits on a global scale.
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Market Segmentations:
Global Distributed Energy Generation Market: By Company
• Bloom Energy
• Capstone Turbine
• General Electric
• Huawei Technologies
• Schneider Electric
• Siemens
• Ballard
• Enercon
• Goldwind
• SMA Solar Technology
• Suzlon
• Yingli Solar
Global Distributed Energy Generation Market: By Type
• Solar PV
• CHP
• Fuel cells
• Wind Power
• Other
Global Distributed Energy Generation Market: By Application
• Rural Areas
• Urban Areas
Global Distributed Energy Generation Market: Regional Analysis
The regional analysis of the global Distributed Energy Generation market provides insights into the market's performance across different regions of the world. The analysis is based on recent and future trends and includes market forecast for the prediction period. The countries covered in the regional analysis of the Distributed Energy Generation market report are as follows:
North America: The North America region includes the U.S., Canada, and Mexico. The U.S. is the largest market for Distributed Energy Generation in this region, followed by Canada and Mexico. The market growth in this region is primarily driven by the presence of key market players and the increasing demand for the product.
Europe: The Europe region includes Germany, France, U.K., Russia, Italy, Spain, Turkey, Netherlands, Switzerland, Belgium, and Rest of Europe. Germany is the largest market for Distributed Energy Generation in this region, followed by the U.K. and France. The market growth in this region is driven by the increasing demand for the product in the automotive and aerospace sectors.
Asia-Pacific: The Asia-Pacific region includes Singapore, Malaysia, Australia, Thailand, Indonesia, Philippines, China, Japan, India, South Korea, and Rest of Asia-Pacific. China is the largest market for Distributed Energy Generation in this region, followed by Japan and India. The market growth in this region is driven by the increasing adoption of the product in various end-use industries, such as automotive, aerospace, and construction.
Middle East and Africa: The Middle East and Africa region includes Saudi Arabia, U.A.E, South Africa, Egypt, Israel, and Rest of Middle East and Africa. The market growth in this region is driven by the increasing demand for the product in the aerospace and defense sectors.
South America: The South America region includes Argentina, Brazil, and Rest of South America. Brazil is the largest market for Distributed Energy Generation in this region, followed by Argentina. The market growth in this region is primarily driven by the increasing demand for the product in the automotive sector.
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#Distributed Energy Generation#Renewable Energy#Solar Power#Wind Energy#Microgrids#Energy Independence#Sustainable Energy#Distributed Generation Technologies#Decentralized Energy#Energy Resilience#Off-Grid Power#Distributed Energy Resources#Local Energy Production#Energy Efficiency#Green Energy#Distributed Energy Solutions#Distributed Solar#Distributed Wind#Distributed Energy Systems#Distributed Power Generation.
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The Power of Progress: Achieving Goal 7 - Affordable and Clean Energy
Energy is the lifeblood of our modern society, driving economic growth, technological advancements, and improving the quality of life for people around the world. However, with the increasing demand for energy, it has become crucial to ensure its affordability and cleanliness. In recognition of this need, the United Nations set forth Goal 7 as part of the Sustainable Development Goals (SDGs) to ensure access to affordable, reliable, sustainable, and modern energy for all. In this article, we will delve into the significance of Goal 7 and explore the transformative power of affordable and clean energy.
The Urgency for Affordable and Clean Energy
Access to affordable and clean energy is not only a matter of convenience but a fundamental requirement for achieving sustainable development. As the global population continues to grow and economies expand, the demand for energy is increasing at an unprecedented rate. However, relying heavily on traditional sources of energy, such as fossil fuels, poses significant challenges for our planet and its inhabitants.
Fossil fuels, including coal, oil, and natural gas, have been the primary sources of energy for many years. While they have fueled industrialization, economic growth, and technological advancements, their negative impact on the environment cannot be ignored. The extraction, production, and consumption of fossil fuels contribute to air and water pollution, deforestation, and the emission of greenhouse gases, primarily carbon dioxide (CO2). These greenhouse gas emissions are the leading cause of climate change, with far-reaching consequences for ecosystems, weather patterns, and human health.
The urgency to transition towards renewable and sustainable sources of energy lies in the need to mitigate the adverse effects of climate change. The Intergovernmental Panel on Climate Change (IPCC) warns that global warming must be limited to well below 2 degrees Celsius compared to pre-industrial levels to avoid catastrophic impacts. Achieving this goal requires a significant reduction in greenhouse gas emissions, which can be achieved by shifting away from fossil fuels and embracing cleaner alternatives.
Renewable energy sources, such as solar, wind, hydro, geothermal, and biomass, offer a promising solution to the challenges of affordability, sustainability, and environmental impact. Unlike fossil fuels, these sources are naturally replenished and emit little to no greenhouse gases during operation. Investing in renewable energy infrastructure and technologies not only reduces our carbon footprint but also enhances energy security, as these sources are virtually inexhaustible.
One of the key advantages of renewable energy is its potential to provide affordable electricity and reduce energy costs in the long run. While the upfront costs of installing renewable energy systems can be higher than traditional fossil fuel-based systems, the operational costs are significantly lower. Solar and wind power, for example, have experienced significant cost reductions over the years, making them increasingly competitive with fossil fuels. As technology advances and economies of scale come into play, the cost of renewable energy is expected to continue declining, making it more accessible to a wider population.
Furthermore, the development and deployment of renewable energy technologies have the potential to create new industries, generate employment opportunities, and stimulate economic growth. The renewable energy sector has already witnessed substantial job creation, with the International Renewable Energy Agency (IRENA) estimating that renewable energy employed around 11.5 million people globally in 2019. Investing in clean energy not only reduces greenhouse gas emissions but also fosters innovation, drives technological advancements, and positions countries at the forefront of the global clean energy transition.
Transitioning to affordable and clean energy is not without its challenges. The current energy infrastructure heavily relies on fossil fuels, and the transition to renewable energy requires substantial investments in renewable energy generation, transmission, and storage systems. Additionally, there are technical and logistical challenges associated with integrating intermittent renewable energy sources into the existing grid infrastructure. However, these challenges can be overcome through comprehensive planning, collaboration between public and private sectors, and supportive policies and regulations.
Governments play a crucial role in facilitating the transition to affordable and clean energy. They can provide financial incentives, subsidies, and tax breaks to encourage investment in renewable energy projects. Policy frameworks that prioritize renewable energy, set renewable energy targets, and establish favorable regulations can create an enabling environment for the growth of the clean energy sector. International cooperation and knowledge-sharing platforms also play a significant role in accelerating the adoption of renewable energy technologies, particularly in developing countries where access to energy is still a challenge.
Access to affordable and clean energy is a fundamental requirement for sustainable development. The urgency lies in transitioning away from fossil fuels and embracing renewable and sustainable sources of energy to mitigate climate change, ensure energy security, and make energy affordable for all. The benefits of this transition extend beyond environmental preservation and include job creation, economic growth, and enhanced resilience. By investing in renewable energy technologies, promoting energy efficiency, and fostering international collaboration, we can pave the way for a sustainable and prosperous future.
Enhancing Energy Efficiency
Improving energy efficiency is a critical aspect of achieving Goal 7 of affordable and clean energy. Energy efficiency refers to the ability to accomplish the same tasks or achieve the same outcomes while using less energy. By adopting energy-efficient technologies, industries, businesses, and households can significantly reduce their energy consumption, leading to multiple benefits such as cost savings and decreased environmental impact.
One of the primary advantages of energy efficiency is its potential to save money. When energy-efficient technologies and practices are implemented, the overall energy consumption decreases, resulting in lower energy bills. For households, this means reduced electricity and heating costs, which can have a positive impact on their monthly budgets. Similarly, businesses and industries can experience substantial cost savings by optimizing their energy use, which can be redirected towards other aspects of their operations or invested in further energy efficiency measures.
Furthermore, energy efficiency plays a crucial role in promoting a sustainable future. By reducing energy consumption, we can alleviate the strain on energy resources and decrease the demand for energy production. This, in turn, reduces the need for the extraction and burning of fossil fuels, thereby mitigating environmental degradation and greenhouse gas emissions. Energy efficiency serves as a crucial tool in combating climate change, as it directly contributes to the reduction of carbon dioxide and other greenhouse gas emissions that are driving global warming.
Investing in energy-efficient appliances, infrastructure, and practices is a key strategy for promoting energy efficiency. Energy-efficient appliances, such as refrigerators, air conditioners, and lighting fixtures, are designed to use less energy while providing the same level of performance. These appliances often carry energy efficiency labels or certifications that help consumers make informed choices when purchasing new products. By opting for energy-efficient appliances, households can significantly reduce their energy consumption without compromising on functionality or comfort.
In addition to appliances, improving the energy efficiency of buildings and infrastructure is essential. This can be achieved through measures such as insulation, efficient windows, and the use of smart technologies that optimize heating, cooling, and lighting systems. Energy-efficient buildings not only save energy but also enhance occupants' comfort, improve indoor air quality, and contribute to a healthier living and working environment.
Energy efficiency practices extend beyond individual households and buildings to industries and businesses. Adopting energy management systems, conducting energy audits, and implementing energy-saving measures can lead to substantial energy savings for industries. These practices can include optimizing production processes, implementing energy-efficient equipment and technologies, and promoting employee awareness and engagement in energy-saving behaviors. Businesses can also benefit from energy efficiency by reducing operating costs and enhancing their reputation as environmentally responsible entities.
Governments also play a vital role in promoting energy efficiency. They can establish energy efficiency standards and regulations for appliances, vehicles, and buildings, ensuring that energy-efficient options are available in the market. Incentives and subsidies can be provided to encourage businesses and households to invest in energy-efficient technologies. Governments can also promote public awareness campaigns and provide educational resources to inform individuals and organizations about the benefits of energy efficiency and how to implement energy-saving practices.
In conclusion, improving energy efficiency is a crucial component of achieving Goal 7 of affordable and clean energy. By adopting energy-efficient technologies, industries, businesses, and households can reduce their energy consumption, resulting in cost savings and decreased environmental impact. Investing in energy-efficient appliances, infrastructure, and practices not only saves money but also contributes to a sustainable future by reducing the demand for energy production and mitigating climate change. Governments, businesses, and individuals must collaborate to prioritize and implement energy efficiency measures, fostering a more sustainable and energy-efficient society.
Embracing Renewable Energy Sources
Renewable energy sources have emerged as a promising solution to address both energy affordability and environmental concerns. Unlike fossil fuels, renewable energy sources such as solar, wind, hydro, geothermal, and biomass offer clean and sustainable alternatives for powering our homes, businesses, and industries. These sources have the potential to provide affordable energy while simultaneously reducing greenhouse gas emissions and decreasing our dependence on fossil fuels.
Solar energy is perhaps one of the most well-known and widely utilized renewable energy sources. Solar panels capture sunlight and convert it into electricity, making it a viable option for generating electricity in residential, commercial, and industrial settings. With advancements in solar technology and decreasing costs, solar power has become increasingly affordable and accessible. Governments and private sectors worldwide are investing in solar energy infrastructure, including large-scale solar farms and rooftop solar installations, to harness the power of the sun and meet energy demands sustainably.
Another renewable energy source gaining significant traction is wind energy. Wind turbines convert the kinetic energy of the wind into electricity. Wind farms, consisting of multiple turbines, are set up in areas with consistent and strong wind patterns. Wind power has seen remarkable growth in recent years, with larger and more efficient turbines being developed. Offshore wind farms, situated in coastal areas, are also being established to take advantage of strong offshore winds. Wind energy has proven to be a cost-effective and environmentally friendly solution, contributing to the reduction of greenhouse gas emissions.
Hydropower harnesses the energy of flowing or falling water to generate electricity. Dams and hydropower plants are built to capture the energy of rivers and convert it into electrical power. Hydropower is a mature and well-established renewable energy source, providing a significant portion of the global electricity supply. It offers a reliable and predictable source of energy, with large-scale hydropower plants capable of generating substantial amounts of electricity. However, there are also smaller-scale hydropower installations, such as run-of-the-river systems and micro-hydropower systems, that can be utilized in remote areas or for local power generation.
Geothermal energy utilizes the heat generated from within the Earth's crust. Geothermal power plants tap into geothermal reservoirs and convert the heat into electricity. This renewable energy source is highly reliable and available 24/7, making it suitable for baseload power generation. Geothermal energy has been utilized in regions with geologically active features such as geysers, hot springs, and volcanic areas. However, advancements in geothermal technology are expanding its potential for wider adoption in various locations worldwide.
Biomass energy involves the use of organic matter, such as wood, agricultural waste, and dedicated energy crops, to generate heat or electricity. Biomass can be burned directly or converted into biofuels, such as ethanol and biodiesel, for transportation and industrial purposes. Biomass energy is considered renewable because the organic matter used for energy production can be replenished through sustainable forestry practices and the cultivation of energy crops. Biomass has the advantage of being a readily available energy source and can provide a reliable energy supply, particularly in rural areas where agricultural and forestry activities are prevalent.
Governments and private sectors worldwide are increasingly recognizing the importance of renewable energy and are investing in the development and deployment of renewable energy infrastructure. Through supportive policies, incentives, and regulatory frameworks, governments are promoting the adoption of renewable energy technologies. They are setting renewable energy targets and implementing feed-in tariffs or power purchase agreements to encourage investment in renewable energy projects. Private sectors are also taking significant steps towards transitioning to renewable energy, with corporations investing in renewable energy projects and setting their own sustainability goals.
The investment in renewable energy infrastructure not only facilitates the transition towards a cleaner and more sustainable energy future but also fosters innovation and creates job opportunities. Renewable energy technologies continue to advance, with ongoing research and development efforts focused on improving efficiency, storage capabilities, and grid integration. The growth of the renewable energy sector has already led to the creation of numerous jobs in manufacturing, installation, operation, and maintenance of renewable energy systems. This sector has the potential to drive economic growth, particularly in regions with abundant renewable resources.
Renewable energy sources offer a promising solution to the dual challenges of energy affordability and environmental concerns. Solar, wind, hydro, geothermal, and biomass energy have demonstrated their potential to provide affordable and clean energy while significantly reducing greenhouse gas emissions. The global shift towards renewable energy is being facilitated by government support, private sector investments, and advancements in technology. By embracing renewable energy sources and fostering the development of renewable energy infrastructure, we can pave the way towards a cleaner, more sustainable, and affordable energy future.
Energy Access for All
Goal 7 of affordable and clean energy also highlights the significance of ensuring energy access for all, including those in remote or underserved areas. It is estimated that approximately 770 million people worldwide still lack access to electricity, which severely hampers their social and economic development. Addressing this issue requires innovative solutions and initiatives that bring reliable and affordable energy to these communities.
Off-grid renewable energy solutions play a crucial role in extending energy access to remote areas. These solutions typically involve the use of decentralized renewable energy systems that are not connected to the centralized grid infrastructure. Off-grid systems, such as solar home systems and small-scale wind turbines, provide electricity for lighting, charging electronic devices, and powering small appliances. These technologies are particularly effective in areas where extending the centralized grid infrastructure is challenging or economically unviable.
Microgrids are another effective approach to bridging the energy access gap. Microgrids are localized energy distribution systems that can operate independently or in conjunction with the main grid. They typically consist of distributed renewable energy generation sources, energy storage, and intelligent control systems. Microgrids are well-suited for providing electricity to communities in remote areas that are not connected to the main grid. They offer a reliable and sustainable energy supply, allowing these communities to access basic services such as lighting, refrigeration, and communication.
Decentralized energy systems are also gaining momentum in addressing energy access challenges. These systems involve the deployment of renewable energy technologies at a local level, such as community-based solar or wind projects. Decentralized energy systems empower communities by giving them control over their energy production and consumption. They promote energy self-sufficiency and resilience, reducing their dependence on centralized power sources and fostering local economic development.
The impact of extending energy access to underserved communities goes beyond simply providing electricity. It has transformative effects on various aspects of their lives. Access to reliable and affordable energy enables communities to engage in productive activities, such as small-scale businesses and income-generating ventures. It opens up opportunities for education, as students can study in well-lit environments and access digital resources. Energy access also enhances healthcare services, allowing clinics and hospitals to operate efficiently with reliable power for medical equipment and refrigeration of vaccines and medicines. Moreover, it improves the overall quality of life, as households can have access to clean and efficient cooking technologies, reducing indoor air pollution and associated health risks.
Initiatives aimed at bridging the energy access gap require collaboration between governments, non-governmental organizations, and the private sector. Governments play a crucial role in developing supportive policies and regulatory frameworks that facilitate the deployment of off-grid and decentralized energy systems. They can provide financial incentives, subsidies, and technical assistance to promote the adoption of clean energy solutions in underserved areas. Non-governmental organizations play a vital role in implementing on-the-ground projects, raising awareness, and mobilizing resources to support energy access initiatives. The private sector, including renewable energy companies, can contribute by investing in and scaling up the deployment of off-grid and decentralized energy solutions.
Achieving Goal 7 of affordable and clean energy requires not only transitioning to renewable energy sources and improving energy efficiency but also ensuring energy access for all. Initiatives such as off-grid renewable energy solutions, microgrids, and decentralized energy systems are instrumental in bringing reliable and affordable energy to underserved communities, particularly in remote areas. Bridging the energy access gap empowers these communities, enabling them to thrive by accessing basic services, engaging in productive activities, and improving their overall quality of life. It is through inclusive and sustainable energy access that we can work towards a more equitable and prosperous future for all.
Public-Private Partnerships for Sustainable Energy
Achieving Goal 7 of affordable and clean energy requires collaborative efforts from governments, businesses, and communities. Public-private partnerships (PPPs) have emerged as effective mechanisms for mobilizing resources, expertise, and innovation towards sustainable energy projects. These partnerships bring together the strengths and capabilities of both sectors, facilitating the transition towards a more sustainable and inclusive energy system.
Governments have a crucial role to play in creating an enabling environment for PPPs to flourish. They can establish supportive policies, incentives, and regulatory frameworks that encourage private sector investment in renewable energy infrastructure. This includes mechanisms such as feed-in tariffs, tax incentives, and streamlined permitting processes for renewable energy projects. By providing a stable and predictable policy framework, governments can mitigate risks and attract private investment.
Furthermore, governments can leverage their procurement power to drive sustainable energy practices. By incorporating sustainability criteria into public procurement processes, governments can create demand for renewable energy technologies and products. This, in turn, stimulates market growth and encourages private sector participation in sustainable energy projects.
The private sector, on the other hand, brings innovation, technical expertise, and financial resources to the table. Businesses can contribute to PPPs through research and development efforts aimed at advancing renewable energy technologies. This includes improving the efficiency, reliability, and cost-effectiveness of renewable energy systems. By investing in research and development, businesses can drive innovation and contribute to the continuous improvement of clean energy technologies.
In addition, the private sector plays a crucial role in financing sustainable energy projects. Through investments in renewable energy infrastructure, businesses can help fund the development and deployment of clean energy technologies. This includes financing options such as project financing, venture capital, and impact investing. By providing financial resources, the private sector can help overcome the upfront costs associated with renewable energy projects, making them more accessible and affordable.
Implementation is another area where PPPs excel. Through collaborative efforts, governments and businesses can work together to implement sustainable energy projects. This includes the construction and operation of renewable energy power plants, the development of energy-efficient buildings and infrastructure, and the deployment of off-grid and decentralized energy systems. The private sector brings project management expertise, technical knowledge, and operational capabilities to ensure the successful execution of these projects.
PPPs also play a significant role in capacity building and knowledge transfer. By partnering with governments, businesses can share their expertise and technical know-how to support the development of local skills and capabilities. This includes training programs, knowledge sharing initiatives, and technology transfer. By building local capacity, PPPs contribute to the long-term sustainability and resilience of energy projects.
Furthermore, PPPs can foster social engagement and community participation. By involving local communities in the decision-making process and project implementation, PPPs can ensure that energy projects address the specific needs and priorities of the communities they serve. This participatory approach promotes social acceptance, enhances local ownership, and maximizes the positive social and economic impacts of sustainable energy projects.
Achieving Goal 7 of affordable and clean energy requires collaborative efforts between governments, businesses, and communities. Public-private partnerships (PPPs) play a crucial role in mobilizing resources, expertise, and innovation towards sustainable energy projects. Governments can create supportive policies and incentives to attract private sector investment, while businesses can contribute through research and development, financing, and project implementation. By joining forces, PPPs can accelerate the transition towards affordable and clean energy, paving the way for a more sustainable future. Together, governments, businesses, and communities can build a resilient and inclusive energy system that benefits society and the planet.
Overcoming Challenges and Barriers
While the transition to affordable and clean energy is promising, there are several challenges and barriers that must be addressed to achieve widespread adoption and implementation. These challenges include the upfront costs of renewable energy infrastructure, technological limitations, and the need for extensive grid integration.
One of the primary challenges is the upfront costs associated with renewable energy infrastructure. While the costs of renewable energy technologies have been steadily declining over the years, they still require significant initial investments. This can pose a barrier, particularly for developing countries and communities with limited financial resources. To overcome this challenge, governments, businesses, and financial institutions need to work together to develop innovative financing mechanisms. Subsidies, grants, and low-interest loans can help make renewable energy projects more financially viable, incentivizing investment and promoting widespread adoption.
Technological limitations are another hurdle in the transition to affordable and clean energy. While renewable energy technologies have made significant advancements, there are still areas that require further research and development. For example, energy storage technologies are crucial for overcoming the intermittent nature of renewable energy sources such as solar and wind. Advancements in energy storage, such as batteries and other innovative storage solutions, are needed to ensure reliable and continuous power supply. Governments and research institutions must invest in research and development efforts to improve the efficiency, durability, and cost-effectiveness of these technologies.
Integration of renewable energy sources into existing energy systems is another significant challenge. The variability and intermittency of renewable energy sources require careful planning and coordination to ensure a stable and reliable energy supply. This involves extensive grid integration and the development of smart grid technologies. Smart grids can enable better management of energy supply and demand, facilitate the integration of renewable energy sources, and enable more efficient distribution of electricity. Governments and energy authorities need to invest in upgrading and modernizing existing grid infrastructure to accommodate renewable energy sources and ensure smooth integration into the energy system.
In addition to these challenges, policy and regulatory frameworks play a crucial role in driving the transition to affordable and clean energy. Governments need to establish clear and supportive policies that provide long-term stability and predictability for renewable energy investments. This includes setting renewable energy targets, implementing feed-in tariffs, and establishing renewable portfolio standards. Additionally, streamlining permitting processes and reducing bureaucratic barriers can help accelerate the deployment of renewable energy projects.
Education and awareness are also essential in overcoming barriers to the transition. Public perception, understanding, and acceptance of renewable energy technologies can significantly impact their adoption. Governments, businesses, and organizations should invest in public awareness campaigns and educational initiatives to promote the benefits of clean energy and address misconceptions or concerns.
Furthermore, international collaboration and knowledge sharing are vital in overcoming challenges and barriers to the transition. Countries and organizations can learn from each other's experiences, best practices, and technological advancements. Platforms for collaboration, such as international conferences, research partnerships, and knowledge-sharing networks, can facilitate the exchange of information and expertise.
In conclusion, while the transition to affordable and clean energy holds great promise, there are several challenges and barriers that need to be addressed. The upfront costs of renewable energy infrastructure, technological limitations, and the integration of renewable energy into existing energy systems are key hurdles. Governments, businesses, and research institutions must invest in research and development to drive down costs, improve efficiency, and enhance grid integration. Additionally, financial mechanisms such as subsidies, grants, and innovative financing models can help make renewable energy projects more financially viable. By overcoming these challenges, we can accelerate the adoption of affordable and clean energy, paving the way for a sustainable and resilient future.
Conclusion
Goal 7 - Affordable and Clean Energy is not just an aspiration; it is a necessity for the sustainable development of our planet. By embracing energy efficiency, transitioning to renewable energy sources, ensuring energy access for all, fostering public-private partnerships, and overcoming challenges, we can unlock the transformative power of affordable and clean energy. The benefits go beyond reducing greenhouse gas emissions and mitigating climate change; they extend to improved public health, economic growth, job creation, and enhanced resilience against energy price fluctuations. Let us collectively work towards a future where energy is affordable, clean, and accessible to all, leaving a positive and lasting impact on generations to come.
#Importance of affordable and clean energy#Achieving sustainable development through affordable energy#Transitioning to clean and affordable energy sources#Renewable energy solutions for a sustainable future#Overcoming barriers to affordable and clean energy#Public-private partnerships for Goal 7#Challenges in achieving affordable and clean energy#Investing in renewable energy infrastructure#Bridging the energy access gap#Role of technology in clean energy transition#Promoting energy efficiency for Goal 7#Impact of renewable energy on climate change#Ensuring energy access for all#Off-grid solutions for energy access#Microgrids and decentralized energy systems#Community empowerment through energy access#Financing renewable energy projects#Policy support for affordable and clean energy#Innovative financing models for renewable energy#Advancements in energy storage technologies#Integrating renewable energy into existing grids#Public perception of clean energy#Social and economic benefits of energy access#Empowering rural communities through energy access#International collaboration for sustainable energy#Achieving energy security through renewable sources#Role of businesses in clean energy transition#Impacts of affordable and clean energy on health#Sustainable energy solutions for developing countries#Future prospects of renewable energy adoption
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Microgrids: Building Resilient And Sustainable Energy Systems
by Envirotech Accelerator
Abstract
Microgrids represent a promising solution to the challenges of energy resilience, sustainability, and access. This article delves into the workings of microgrids, their benefits, and potential applications, highlighting their significance in shaping a more sustainable future.
Introduction
Microgrids are localized energy systems capable of operating independently from the main power grid. James Scott, founder of the Envirotech Accelerator, posits, “Microgrids are not just a technological advancement; they are a paradigm shift, ushering in a new era of decentralized, resilient, and sustainable energy systems.” This article explores the characteristics of microgrids, their advantages, and their potential to revolutionize energy infrastructure.
Microgrid Components and Operation
Microgrids consist of diverse elements, including power generation sources, energy storage systems, and distribution networks (Lasseter & Paigi, 2004). They can incorporate renewable energy, such as solar or wind, along with conventional generators, and utilize batteries or other storage technologies. Microgrids use advanced control systems to manage energy supply and demand, ensuring stable and efficient operation.
Benefits of Microgrids
Resilience: Microgrids improve energy system resilience by maintaining power supply during grid disruptions or extreme weather events (Erol-Kantarci & Mouftah, 2015). Their decentralized nature reduces the risk of widespread outages, enhancing overall grid stability.
Sustainability: Incorporating renewable energy sources, microgrids can reduce greenhouse gas emissions and reliance on fossil fuels. They also promote energy efficiency, as localized generation reduces transmission losses.
Access: Microgrids can provide energy access to remote or off-grid communities, enabling socioeconomic development and improved quality of life (Palit & Chaurey, 2011).
Applications of Microgrids
Remote Communities: Microgrids can bring electricity to isolated areas, replacing costly and polluting diesel generators with clean, renewable energy.
Disaster Response: In disaster-affected regions, microgrids can rapidly restore power, supporting critical services and facilitating recovery efforts.
Industrial and Commercial Facilities: Microgrids can ensure reliable power supply for energy-intensive operations, reducing downtime and improving efficiency.
Conclusion
Microgrids offer a transformative approach to energy generation and distribution, enhancing resilience, sustainability, and access. By embracing microgrid technology, we can foster a more decentralized and robust energy infrastructure, laying the foundation for a sustainable future.
References
Erol-Kantarci, M., & Mouftah, H. T. (2015). Energy efficiency in smart grids: A survey. IEEE Communications Surveys & Tutorials, 17(4), 2312–2335.
Lasseter, R. H., & Paigi, P. (2004, October). Microgrid: A conceptual solution. In PESC Record. IEEE 35th Annual Power Electronics Specialists Conference, 2004. (Vol. 6, pp. 4285–4290). IEEE.
Palit, D., & Chaurey, A. (2011). Off-grid rural electrification experiences from South Asia: Status and best practices. Energy for Sustainable Development, 15(3), 266–276.
Read more at Envirotech Accelerator.
#James Scott#Envirotech Accelerator#James Scott microgrids#Envirotech Accelerator energy resilience#James Scott sustainable energy systems#Envirotech Accelerator microgrid applications#James Scott decentralized energy#Envirotech Accelerator renewable integration#James Scott energy access#Envirotech Accelerator smart grids#James Scott grid stability#Envirotech Accelerator energy efficiency
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Klean Industries Partners With H2Core Systems for the Rollout of Containerized Hydrogen Production Facilities
Klean Industries Partners With H2Core Systems for the Rollout of Containerized Hydrogen Production Facilities
VANCOUVER, British Columbia, November 7, 2022 (Newswire.com)
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Klean Industries Inc (“Klean”), a leading equipment manufacturer that owns a commercialized portfolio of intellectual properties and know-how focusing on the recovery of clean energy and resources from waste, is pleased to announce that it has signed a partnership agreement with H2 Core Systems (“H2 Core”) to distribute and build…
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#Anion Exchange Membrane (AEM)#Circular Economy#Decentralized Energy#e-fuels#Enapter AEM electrolysers#esg#Green Hydrogen#H2 Core Systems#Renewable Fuels#Waste to Energy#Waste to Hydrogen
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Excerpt from this Op-Ed from the New York Times:
At first glance, Xi Jinping seems to have lost the plot.
China’s president appears to be smothering the entrepreneurial dynamism that allowed his country to crawl out of poverty and become the factory of the world. He has brushed aside Deng Xiaoping’s maxim “To get rich is glorious” in favor of centralized planning and Communist-sounding slogans like “ecological civilization” and “new, quality productive forces,” which have prompted predictions of the end of China’s economic miracle.
But Mr. Xi is, in fact, making a decades-long bet that China can dominate the global transition to green energy, with his one-party state acting as the driving force in a way that free markets cannot or will not. His ultimate goal is not just to address one of humanity’s most urgent problems — climate change — but also to position China as the global savior in the process.
It has already begun. In recent years, the transition away from fossil fuels has become Mr. Xi’s mantra and the common thread in China’s industrial policies. It’s yielding results: China is now the world’s leading manufacturer of climate-friendly technologies, such as solar panels, batteries and electric vehicles. Last year the energy transition was China’s single biggest driver of overall investment and economic growth, making it the first large economy to achieve that.
This raises an important question for the United States and all of humanity: Is Mr. Xi right? Is a state-directed system like China’s better positioned to solve a generational crisis like climate change, or is a decentralized market approach — i.e., the American way — the answer?
How this plays out could have serious implications for American power and influence.
Look at what happened in the early 20th century, when fascism posed a global threat. America entered the fight late, but with its industrial power — the arsenal of democracy — it emerged on top. Whoever unlocks the door inherits the kingdom, and the United States set about building a new architecture of trade and international relations. The era of American dominance began.
Climate change is, similarly, a global problem, one that threatens our species and the world’s biodiversity. Where do Brazil, Pakistan, Indonesia and other large developing nations that are already grappling with the effects of climate change find their solutions? It will be in technologies that offer an affordable path to decarbonization, and so far, it’s China that is providing most of the solar panels, electric cars and more. China’s exports, increasingly led by green technology, are booming, and much of the growth involves exports to developing countries.
From the American neoliberal economic viewpoint, a state-led push like this might seem illegitimate or even unfair. The state, with its subsidies and political directives, is making decisions that are better left to the markets, the thinking goes.
But China’s leaders have their own calculations, which prioritize stability decades from now over shareholder returns today. Chinese history is littered with dynasties that fell because of famines, floods or failures to adapt to new realities. The Chinese Communist Party’s centrally planned system values constant struggle for its own sake, and today’s struggle is against climate change. China received a frightening reminder of this in 2022, when vast areas of the country baked for weeks under a record heat wave that dried up rivers, withered crops and was blamed for several heatstroke deaths.
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What differentiates the fragile and polluting farm economy we have today from one that regenerates the land while producing a diversity of food in an unstable climate? The fundamental difference between these two farm economies is that one is capital-intensive, while the other is management-intensive. A management-intensive operation is one in which the primary asset of the agricultural operation is the observation, engagement and intervention by farm workers.7 A management-intensive operation simply has far more farm worker engagement per acre than a capital-intensive operation. In a capital-intensive operation, the primary assets are capital investments acquired using loans from a bank, which are then utilized to operate at the greatest scale possible using as little labor as possible, with the goal of reducing production costs and maximizing profit through the achievement of economies of scale. Both management- and capital-intensive operations utilize labor and capital to achieve a yield. What differentiates them is the balance between labor and capital.
Management-intensive farms tend to be smaller, as the importance of human observation and engagement acts as a natural barrier to developing scale. These smaller farms also tend to be more diverse, as crop rotation and the inclusion of animals are prioritized in order to maximize ecosystem health and to reduce inputs. A system of small, management-intensive farms working in a decentralized self-organizing network would mirror the resilience, productivity and diversity of an ecosystem that has been freed from industrial disturbance. What a healthy ecosystem demonstrates is that the most efficient means of cycling energy within a system is through a complex network of relationships between mutually beneficial organisms. It is resilient not just because it is diverse, but because it is a decentralized self-organizing system, wherein portions of the system are capable of functioning on their own should they be severed from the larger network. These are the features that we should be trying to replicate as we design a new agricultural economy. By orienting ourselves towards management-intensive operations, we would be doing just that.
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I'd like to present to you a solarpunk flag!
This flag was designed and drawn by @himokors
It has very blury meaning but it goes like that:
The center symbolizes both the sun (the purest energy) and the sunflower 🌻 - a magnificent plant with numerous uses, and once again, as a symbol of the sun and prosperity.
The multitude of white dots represents the Dyson swarm, symbolizing the method of harvesting solar energy and a decentralized system of management, where individual people are united in an alliance working for the common good and moving together towards a noble idea.
The three dots at the top represent RRR - Reduce, Reuse, Recycle (and other meanings if they can be imagined). Individual elements only make sense when viewed in the context of the entire flag.
This flag is free to use for everyone who likes it!
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Simple tool for newsletters, SMS and marketing automation for experts who market knowledge
Create and send professional newsletters and highly profitable automated marketing campaigns. KlickTipp wins new recipients for you 24/7 and turns them into enthusiastic, paying customers.
You can also try this product The KlickTipp
You can also try this product The KlickTipp
DISCLAIMER
There are an affliate link of best product in this
article which may make some profit for me
#agencies#doctor's offices#car dealerships#coaches#consultants#decentralized energy systems#energy supplier#event industry#gyms#photography & film#franchising#drinks & Food#craft terrace construction#craftcarpenter#real estate agent#info marketer#engineering offices#farmers#mechanical and plant engineering#online conference organizer#expert#seminar provider#software & IT#speaker#tax consultant#therapists#coach#trainer#business consultant#associations
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pluto in aquarius rambles
Pluto in Aquarius = Power to the People
Pluto = Power
Aquarius = Human, the Water Bearer, rules Groups of people, and demagogues.
I have several predictions based on Pluto in Aquarius. Pluto in Aquarius will be ruled by a Saturn in Pisces when it moves on Jan 20th, 2024... and as we can see, people are receiving reprecussions (Saturn) based on their Beliefs (Pisces)
Previously, I’ve predicted that it would be the Fall of Silicon Valley. In fact, while Pluto was briefly in Aquarius this year, Saturn stationed in Pisces on March 7th (One day before my birthday, lol) and Silicon Valley Bank ended up doing a bank run.
EDIT: 02/23. I just checked. Saturn did go into Pisces 03/07, but Pluto wasn’t in Aquarius until 03/23. I do consider Pluto to rule financial systems, and I do think the Saturn transit did spark the bank run, but I wanted to correct this! I am sorry! Pluto spiked the same bank run on Black Monday 2008, and led to the subprime mortgage crisis. So, Saturn-Pluto, but NOT Pluto in Aquarius. I apologize.
I think it’s fun to use astrology in tandem with what we’re experiencing because as above, so below. But, it’s more fun to be able to recognize the energy that you’re looking at.
So, here’s a little loose list of things that I think will happen during Pluto in Aquarius.
1. Power (Pluto) to the People (Aquarius) = Our reliance on these big corporate structures (Capricorn) will lower and lower, especially as we see ourselves getting punished for speaking about what we believe in. I feel like we will question sources of power, and then look into finding our power within ourselves. I feel like there will be more demagogues lol. But mostly, it will be people turning to their communities.
2. Political Revolutions - Last time Pluto was in Aqua was from 1778-1798 and I swear to god they got that bitch cracking like CRAB LEGS. They had
Irish Rebellion
Settler-Indigenous Wars
Indigenous rebellion against spanish colonization
Haitian Revolution
Northwest Indian War …
Like THEY WASN’T FUCKING PLAYING. So, you already know what time it is. I guess my question is how will the INTERNET play into this?
3. Ass play is about to be as common as kissing in my opinion.
4. Here’s more general predictions lol
cyber crimes, technological terrorism worse than data breaching, pen testing (Pluto = Terrorist activity)
online tombs
cyberpollution
Camgirling is about to change in a new way.
Digital sex work
Digital smut (erotica writers? You’re up)
Digital Decay will be addressed. We will see the first ruined images due to natural jpeg artifact build up
Digital Third Space/Metaverse will be expanded upon. Focusing on a decentralization of both this technology and the need for this “digital third space” will help this from being some terrorist rich kids fantasy.
4. OH AND LIKE I FUCKING SAID. SILICON VALLEY WILL FALL.
5. 3D is up, more focus on 3D. I saw a tweet about that, but I think that a lot of the kids will be more advanced at 3D vs how we as kids went towards digital art? Idk how to make that make sense but yea.
6. Cybertheft. Feels like there is about to be A GLARING VULNERABILITY LOL THAT JUST WENT UNCOVERED UNTIL NOW and it will get EXPLOITED AND TORE TF UP
7. Everybody thinks they’re fuckin Jon Stewart … one thing I haye about us Aquarii we don’t know how to shut the fuck up sometimes…
8. Streamers held the long con enough for people to forget responsible pirating, but this will turn on its head during this transit I think…
9. Looking at the internet….
Pluto rules generations. So pluto in Aquarius will be a new generation. And they will be weird as hell.
Pluto in Scorpio = When World Wide Web was created.
Pluto in Aquarius = WWW Square. And I feel like now, we’re looking at the damages and transformations the internet underwent since the web was created. It feels much more hollow.
I think Pluto Squares tell us how to fix things. Just saying.
This is all I have… for now….
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Horus Balor
As is the case with most HORUS pattern groups, the Balor has a thousand faces. The Balor pattern group, like all HORUS PGs, doesn’t describe a single recognizable silhouette so much as it gestures toward a combination of schemata that share a role in combat. These schemata can be printed according to pilot specifications and applied to a fully custom physical scaffolding. Notably, the Balor pattern group is only stable on large platforms (Schedule 2 and up) that are able to provide the raw energy output it demands – preferably ones with multiple redundancies, in case of catastrophic systems failure.
The Balor PG was first encountered during the joint Albatross–DoJ/HR pursuit of the Maw – a Free Company turned decentralized hive-being — across Khayradin’s Blanca Desert after the end of the Sanjak Rebellion. It was there that the joint force encountered, engaged with, and ultimately defeated the Maw and its Balors – and there that Union’s CentComm hoped the nanowash outbreak could be contained. Of course, subsequent Balor outbreaks on Khayradin have proven this hope to be in vain, and the pattern group continues to terrorize Karrakin commanders throughout Baronic space.
In the field, the Balor’s neurosynced hellswarm and greywash nanites form an undulating shroud that can pour out of its chassis at a moment’s notice, swirling in maddening patterns to form both eschatologic defensive and offensive systems. A Balor in its most active state is held together more by undulating, flame-like masses of nanite swarms than any physical structure. This has the effect of distributing kinetic and coherent-particle energy out across and through the chassis – making attacks against a Balor “like shooting angry water”, as one after-action report put it.
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Can you help debunk what I have been told that solar panels are bad for the environment and cause more waste because they take a long time to decompose and wear out in a couple years?
Okay, let me try and answer this. Because yes, this is a more complicated issue, than a lot of people make it out to be.
So, let me start with the big thing that gets often overlooked: Without even looking into ressource use, big photovoltaic power plans have definitely a negative environmental impact. Not as a negative as anything fossil energy related, but negative never the less.
With power plants I mean those giant fields where we plaster photovoltaic panels over acres of land, to have a central power plant based around photovoltaic. And while we might not get around some of those big power plants, part of the energy revolution should be to move towards micro grids instead of current macro grids (so, decentralization), hence lowering the need of central powerplants.
Now, a lot of people who are anti-pv - mostly people who are from the fossil fuel lobby, but also some nuclear-lobby folks - tend to exaggerate those negative impacts... But they are still there. (Mostly having to do with depending on the type of pv panel used they can impact the ground temperature - and of course they just disrupt the environment.)
Sooo... Let's get to the raw materials. The important bit in photovoltaic is silicon. And this is one of the good old environmentalist "well actaully" things. Because when I was a kid I got told: "Oh, silicon is never a problem, because it is just sand! We have so much sand!" But of course I learned that it is not quite as easy. Because not all sand is created equal and not all can be used for stuff like concrete (which is shit either way), glass or photovoltaic.
Though still it is not as much of an issue as a lot of rare earth materials. Some of which are currently used in photovoltaic. But here is the other thing...
Photovoltaic is currently one of the fastest developing energy technologies. Basically anything I am gonna tell you here will be outdated next year. I guarantee.
But yes, in the creation of photovoltaic we currently use rare earth metals, that are at times sourced through bad means. Both in terms of it being mined through slave work and through the mining being done in a way that harms the environment. But... for one, we are currently working on reducing the need for rare earth metals in the creation of photovoltaic. And like with nuclear materials: We could mine the materials in a much more sustainable way - both on a social and ecological level. It is just that the current capitalist system has all the incentives to mine those materials wiht exploited workers or even slaves, and to not take care of the waste created in the mining operation.
And this gets us back to the recycling.
Short version: Yeah, we have ways to recycle about 65-80% of the materials in a photovoltaic panel. And like everything else: We are working on it and it will probably go up to 90%. But once again: Like with all recycling the issue is, that recycling materials is way more expensive than getting new materials. Which is why under capitalism all the things we could recycle often do not get recycled.
But it is possible.
tl;dr: Yes, there are drawbacks to photovoltaic, but it is not as bad as many make it seem. And a ton of the drawbacks are not inevitable but only exist because of capitalism.
#solarpunk#photovoltaic#solar#solar power#solar energy#recycling#environmentalism#sustainability#anti capitalism
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Kintype Anatomical Diagram - 2024 Revamp!
Thought the old schematic was outdated enough, so here's a new one! Probably not realistically feasible in some parts, so take it more as a fun creative exercise :] More systems have been laid out due to a different style for showing everything.
Text transcript under the cut:
Jupiter DromaeOS - Rough Schematic
Height - 6'1/2" / 198cm
Tail Length - 4'8" / 142cm
Weight - 215lb / 97.5kg
Composition is largely of carbon, with smaller amounts of silicon, gold, iron, water, and other trace elements.
Skeletal System
Compacted carbon for support and structural integrity
Braced in certain areas
Ribs divided to allow movement of storage compartments
Electric System
Provides energy for most bodily functions
A. Power Supply Unit - Allows charging from an external energy grid. Requires power cable
B. Solar Panels - Carbon-perovskite photovoltaics for use when away from an energy grid. Usually hidden under feathers
C. Battery - Lithium-sulfur solid state battery that provides ~48 hours of waketime when fully charged
D. Solid State Drive - Extra storage capacity for important memories and information
E. Graphics Processing Unit - Renders AR and holo-displays, as well as internal simulations and dreams
Circulatory System
Circulates around the body a kind of “blood” made of nanites and liquid coolant. Waste heat ejected through fans on the back of the body
F. Nanite Hub - Pumps nanite blood throughout the body. Also houses a nanite fabricator and programmer
Nervous System
Houses most processing power, tactile sense, and consciousness. Comprised of artificial neurons that require a constant supply of electricity
G. Central Processing Unit - Standard issue synthetic humanoid brain. Structure indicates a nontrivial level of neurodivergence
Digestive System
Processes traditional food and certain kinds of inorganic matter. Essential for self-repair and can have a positive effect on mental state
H. Crusher - For chewing both organic and inorganic matter. Soundproofed by skeletal structure in snout
I. Pseudostomach - Dissolves consumed material with nanites rather than acid
J. Graphene Production Chambers - Produces graphene for use in repairs via flash joule heating. Leftover material deposited in lowest storage compartments for use as printer feedstock
Storage Compartments
Built-in drawers for storing goods and materials. Can be refrigerated via circulatory system
Sensory and Communication Devices
K. Microphones - Ear equivalent, input volume can be adjusted or muted
L. Speaker - Vocal output device, can produce a wide array of sounds and can be modulated
M. Eyes - Light passes through display screens used for visual communication
N. AR lens - Projects private-use visual overlays
O. Retinas - Collects modified light signal and sends to CPU and GPU
P. Wireless Internet Receiver - Fully-controlled access to decentralized internet. Uses secondary displays rather than direct input into CPU
Q. Nostrils & Tongue - Detect presence of chemicals in air and food, output converted into signals directed towards CPU
Rockets
Provide mobility within aerospace
R. Microthrusters - Small ion thrusters for stabilization in microgravity
S. Liquid Fuel/Oxidizer Storage - Frozen when not in use to reduce balance issues
T. Pumps - Carry fuel and oxidizer into combustion chamber
U. Combustion Chamber - Mixes and burns fuel and oxidizer
V. Nozzle - Rocket exhaust exits through soles to create thrust
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