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Heat recovery methods play a pivotal role in maximizing energy efficiency and sustainability across various industries. In a world increasingly focused on resource conservation and environmental responsibility, the concept of recovering and repurposing heat has become integral to modern engineering and technology. This preface aims to provide an introductory overview of the significance of heat recovery methods, exploring their applications, benefits, and the growing importance of these techniques in the context of energy conservation and environmental stewardship. Introduction to Heat Recovery: Heat recovery involves capturing and utilizing thermal energy that would otherwise be lost during industrial processes, power generation, or HVAC operations. This reclaimed heat can be repurposed for various applications, such as space heating, water heating, or to enhance the efficiency of other processes. Applications Across Industries: Heat recovery methods find applications in diverse industries, including manufacturing, power generation, transportation, and building services. In manufacturing, for instance, heat recovery from industrial processes can lead to significant energy savings. Similarly, power plants can employ heat recovery systems to boost overall efficiency by capturing and utilizing waste heat. Technological Diversity: Various heat recovery technologies and systems contribute to this endeavor, ranging from heat exchangers and cogeneration (combined heat and power) systems to more specialized solutions like desiccant wheels and thermal storage. Each method addresses specific operational needs, providing a versatile toolkit for engineers and system designers. Environmental and Economic Impact: Beyond their technical prowess, heat recovery methods make a substantial contribution to environmental sustainability. By reducing the demand for additional energy inputs, these methods aid in mitigating greenhouse gas emissions and diminishing reliance on finite resources. Simultaneously, the economic benefits of improved energy efficiency underscore the financial advantages of adopting heat recovery practices. Challenges and Opportunities: While heat recovery holds immense promise, its widespread adoption faces challenges related to system integration, infrastructure, and economic considerations. Striking a balance between initial investment costs and long-term savings remains a crucial aspect of decision-making. However, as technological advancements continue, opportunities emerge to overcome these challenges, making heat recovery an increasingly viable and attractive option for industries worldwide. Conclusion: Heat recovery methods represent a cornerstone of sustainable and responsible energy management. As industries and societies strive to meet ambitious energy efficiency goals and reduce their environmental footprint, the role of heat recovery becomes ever more crucial. This exploration of heat recovery methods sets the stage for a deeper dive into specific technologies and applications, shedding light on the innovations driving the transition towards a more energy-efficient and environmentally conscious future.
Thermal Methods, Volume Two, the latest release in the Enhanced Oil Recovery series, helps engineers focus on the latest developments in this fast-growing area. In the book, different techniques are described in addition to the latest technologies in data mining and hybrid processes. Supported field case studies are included to illustrate a bridge between research and practical applications, making it useful for both academics and practicing engineers. Structured to start with thermal concepts and steam flooding, the book's editors then advance to more complex content, guiding engineers into areas such as hybrid thermal methods and edgier technologies that bridge solar and nuclear energy. Supported by a full spectrum of contributors, this book gives petroleum engineers and researchers the latest research developments and field applications to drive innovation for the future of energy. Presents the latest understanding surrounding the updated research and practical applications specific to thermal enhanced oil recovery methods Provides an analysis of editors’ research on available technology, including hybrid thermal-solvent processes and dual pipe configurations Teaches about additional methods, such as data mining applications, and economic and environmental considerations
Describes the recovery of heavy oils and bitumen by in situ thermal methods and discusses the technical factors and problems involved. The book summarizes, in a quantitative manner, techniques used in current petroleum industry practice.
This book introduces two of the most exciting heat pumping technologies, the coabsorbent and the thermal recovery (mechanical vapor) compression, characterized by a high potential in primary energy savings and environmental protection. New cycles with potential applications of nontruncated, truncated, hybrid truncated, and multi-effect coabsorbent types are introduced in this work. Thermal-to-work recovery compression (TWRC) is the first of two particular methods explored here, including how superheat is converted into work, which diminishes the compressor work input. In the second method, thermal-to-thermal recovery compression (TTRC), the superheat is converted into useful cooling and/or heating, and added to the cycle output effect via the coabsorbent technology. These and other methods of discharge gas superheat recovery are analyzed for single-, two-, three-, and multi-stage compression cooling and heating, ammonia and ammonia-water cycles, and the effectiveness results are given. The author presents absorption-related topics, including the divided-device method for mass and heat transfer analysis, and truncation as a unique method for a better source-task match. Along with advanced gax recovery, the first and second principles of COP and exergy calculation, the ideal point approaching (i.p.a.) effect and the two-point theory of mass and heat transfer, the book also addresses the new wording of the Laplace equation, the Marangoni effect true explanation, and the new mass and heat exchangers based on this effect. The work goes on to explore coabsorbent separate and combined cooling, heating, and power (CHP) production and advanced water-lithium bromide cycle air-conditioning, as well as analyzing high-efficiency ammonia-water heat-driven heating and industrial low-temperature cooling, in detail. Readers will learn how coabsorbent technology is based on classic absorption, but is more general. It is capable of offering effective solutions for all cooling and heating applications (industry, agriculture, district, household, etc.), provided that two supplying heat-sink sources with temperatures outdistanced by a minimum of 12-15oC are available. This book has clear and concise presentation and illustrates the theory and applications with diagrams, tables, and flowcharts.
The book details sources of thermal energy, methods of capture, and applications. It describes the basics of thermal energy, including measuring thermal energy, laws of thermodynamics that govern its use and transformation, modes of thermal energy, conventional processes, devices and materials, and the methods by which it is transferred. It covers 8 sources of thermal energy: combustion, fusion (solar) fission (nuclear), geothermal, microwave, plasma, waste heat, and thermal energy storage. In each case, the methods of production and capture and its uses are described in detail. It also discusses novel processes and devices used to improve transfer and transformation processes.
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