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Futuristic Projects in Energy and Automation Sectors is a review of analyses on energy transitions in power grids and the opportunities and challenges for building sustainable energy systems to improve human capabilities. 14 chapters examine renewable energy-based and automated systems, with a focus on projects that are designed with sustainability in mind. Topics covered in this review include 1) power systems, 2) renewable energy, 3) power electronics, 4) energy storage and conversion, 5) home automation, 6) control systems, 7) robotics, 8) artificial intelligence, and 9) technology to fight COVID-19. This review will be of interest to scholars, and policymakers interested in futuristic and urban and rural energy planning, sustainable and renewable energy projects, sustainable development, and environment management.
Futuristic Projects in Energy and Automation Sectors is a review of analyses on energy transitions in power grids and the opportunities and challenges for building sustainable energy systems to improve human capabilities. 14 chapters examine renewable energy-based and automated systems, with a focus on projects that are designed with sustainability in mind. Topics covered in this review include 1) power systems, 2) renewable energy, 3) power electronics, 4) energy storage and conversion, 5) home automation, 6) control systems, 7) robotics, 8) artificial intelligence, and 9) technology to fight COVID-19.This review will be of interest to scholars, and policymakers interested in futuristic and urban and rural energy planning, sustainable and renewable energy projects, sustainable development, and environment management.
This book presents the scientific outcomes of the International Conference AUTOMATION 2020, held on March 18–20, 2020 in Warsaw, Poland. The next 30 years will see radical innovations in production processes, transportation management and social life. The changes brought about by the transformation to zero-emission industry require advances in many fields, but especially in industrial automation, robotics and measurement techniques associated with the cyber-physical systems employing artificial intelligence that will be key to reducing costs and enabling European society to maintain its quality of live. In this context, the book features the latest research toward further developing these fields of engineering, and also offers solutions and guidelines that are useful for both researchers and engineers addressing problems associated with the world of ongoing radical changes.
Fasteners Manufacturing 1. Market Overview: The fasteners manufacturing industry is a crucial component of the global manufacturing and construction sectors. Fasteners are essential in joining and securing various components in machinery, automotive, construction, aerospace, and other industries. The global fasteners market has witnessed steady growth due to the increasing demand for durable and reliable fastening solutions across industries. 2. Market Segmentation: The fasteners manufacturing market can be segmented as follows: a. Product Type: • Bolts • Screws • Nuts • Rivets • Washers • Others b. Material: • Steel • Aluminum • Brass • Plastic • Others c. End-Use Industry: • Automotive • Construction • Aerospace • Electronics • Energy • Industrial Machinery • Others 3. Regional Analysis: The global fasteners market is distributed across several regions: • North America: High demand due to the automotive and construction industries. • Europe: Strong market presence, especially in automotive manufacturing. • Asia-Pacific: Dominant due to rapid industrialization and construction activities. • Middle East and Africa: Steady growth driven by infrastructure development. • Latin America: Increasing demand in the construction and aerospace sectors. 4. Market Drivers: • Global Infrastructure Development: Increasing construction activities worldwide drive demand for fasteners. • Automotive Industry Growth: The automotive industry's expansion fuels demand for high-quality fasteners. • Industrialization: Ongoing industrialization in emerging markets boosts the manufacturing sector. • Aerospace Advancements: Advancements in aerospace technologies require specialized fasteners. 5. Market Challenges: • Fluctuating Raw Material Prices: The fasteners industry is sensitive to fluctuations in metal and alloy prices. • Environmental Regulations: Compliance with environmental regulations poses challenges in material usage and disposal. • Intense Competition: The market is highly competitive, leading to price wars. 6. Opportunities: • Customization: Meeting specific industry needs with tailor-made fasteners. • Eco-friendly Solutions: Developing sustainable and recyclable fasteners. • Digitalization: Embracing Industry 4.0 for improved production processes. 7. Future Outlook: The fasteners manufacturing industry is expected to continue its growth trajectory, driven by global economic recovery, infrastructure investments, and technological advancements. The market is likely to witness an increasing shift toward lightweight materials and sustainable fastening solutions. Conclusion: The global fasteners manufacturing industry is a vital part of various sectors, ensuring the safety and reliability of products worldwide. With a diverse range of products, materials, and end-use industries, the market offers opportunities for innovation and growth. However, it also faces challenges related to raw material prices and environmental regulations. To stay competitive, companies should focus on customization, sustainability, and digitalization to meet the evolving demands of industries worldwide. The future of fasteners manufacturing looks promising as it continues to adapt to the changing global landscape.
Innovations, Disruptions and Future Trends in the Global Construction Industry examines current and futuristic developments in the construction industry hinged on the construction industrial fourth and fifth revolution, otherwise known as construction industry 4.0 and 5.0. This book provides a wide range of expert views and case studies on the future of the construction industry from the perspectives of researchers and practitioners in various fields of study from business management, psychology, sociology, engineering, behavioural studies and computer sciences. The book provides documentary evidence of how the construction industry has changed post-COVID-19 pandemic in terms of design, planning, management, construction, the behaviour of construction professionals, research in the built environment, and new interactions of built environment practitioners with other professionals from computer science, finance, business management, and engineering. The evidence provided in this book can help decision makers in the construction sector and associated industries to understand human interaction in the construction sector and inspire new research directions. Furthermore, the book will map potential future paradigms for the construction industry and the preparedness of construction professionals, teams, and organisations for coming changes. This book is of interest to a wide audience of postgraduate students, academics, researchers, and industry professionals in the built environment, finance, project management, engineering, and policy makers.
Looking for ways to handle the transition to a digital economy Robots, artificial intelligence, and driverless cars are no longer things of the distant future. They are with us today and will become increasingly common in coming years, along with virtual reality and digital personal assistants. As these tools advance deeper into everyday use, they raise the question—how will they transform society, the economy, and politics? If companies need fewer workers due to automation and robotics, what happens to those who once held those jobs and don't have the skills for new jobs? And since many social benefits are delivered through jobs, how are people outside the workforce for a lengthy period of time going to earn a living and get health care and social benefits? Looking past today's headlines, political scientist and cultural observer Darrell M. West argues that society needs to rethink the concept of jobs, reconfigure the social contract, move toward a system of lifetime learning, and develop a new kind of politics that can deal with economic dislocations. With the U.S. governance system in shambles because of political polarization and hyper-partisanship, dealing creatively with the transition to a fully digital economy will vex political leaders and complicate the adoption of remedies that could ease the transition pain. It is imperative that we make major adjustments in how we think about work and the social contract in order to prevent society from spiraling out of control. This book presents a number of proposals to help people deal with the transition from an industrial to a digital economy. We must broaden the concept of employment to include volunteering and parenting and pay greater attention to the opportunities for leisure time. New forms of identity will be possible when the "job" no longer defines people's sense of personal meaning, and they engage in a broader range of activities. Workers will need help throughout their lifetimes to acquire new skills and develop new job capabilities. Political reforms will be necessary to reduce polarization and restore civility so there can be open and healthy debate about where responsibility lies for economic well-being. This book is an important contribution to a discussion about tomorrow—one that needs to take place today.
The Energy and Climate Change Committee believes the UK could become a leading exporter of wave and tidal power equipment and expertise if the Government adopts a more visionary approach to developing marine renewables. Technologies that can harness the power of the sea to generate electricity are still in their infancy. But with the largest wave and tidal resources in Europe, up to 20% of the UK's electricity could eventually come from this reliable and predictable low-carbon source. Developing a thriving wave and tidal industry could also bring economic benefits to the UK. Companies based here could export equipment and components for marine devices to other markets, and also provide specialist skills and expertise, such as offshore surveying. The UK is currently the world leader in the development of wave and tidal energy technologies. Of the eight full-scale prototype devices installed worldwide, seven are in the UK. But an overly cautious approach to developing this sector may allow other less risk-averse countries to steal the UK's lead, as happened with wind turbines. The report identifies a number of crucial areas for development of the marine renewables industry: investor confidence, policy certainty, public-private risk sharing, improved grid connections and a workforce with the necessary engineering skills are all. The UK needs a strong political vision to boost confidence and drive the pace of development in order to reap the rewards of a successful wave and tidal power industry.
The book provides a comprehensive overview of the most recent and advanced research findings on energy production and management in the important Ural industrial region of Russia. The authors consider economic problems of energy development, management systems for sustainable energy, and investment mechanisms for energy. Comprised of chapters on energy efficient technologies, environmental aspects of using energy, and personnel for the power industry, the volume is ideal for a range of scientists and engineers interested in innovative approaches to generation and distribution of energy.
The advancement of sustainable energy is becoming an important concern for many countries. The traditional electrical grid supports only one-way interaction of power being delivered to the consumers. The emergence of improved sensors, actuators, and automation technologies has consequently improved the control, monitoring and communication techniques within the energy sector, including the Smart Grid system. With the support of the aforementioned modern technologies, the information flows in two-ways between the consumer and supplier. This data communication helps the supplier in overcoming challenges like integration of renewable technologies, management of energy demand, load automation and control. Renewable energy (RE) is intermittent in nature and therefore difficult to predict. The accurate RE forecasting is very essential to improve the power system operations. The forecasting models are based on complex function combinations that include seasonality, fluctuation, and dynamic nonlinearity. The advanced intelligent computing algorithms for forecasting should consider the proper parameter determinations for achieving optimization. For this we need, new generation research areas like Machine learning (ML), and Artificial Intelligence (AI) to enable the efficient integration of distributed and renewable generation at large scale and at all voltage levels. The modern research in the above areas will improve the efficiency, reliability and sustainability in the Smart grid.