Fabrication of Metallic Pressure Vessels


Book Description

Fabrication of Metallic Pressure Vessels A comprehensive guide to processes and topics in pressure vessel fabrication Fabrication of Metallic Pressure Vessels delivers comprehensive coverage of the various processes used in the fabrication of process equipment. The authors, both accomplished engineers, offer readers a broad understanding of the steps and processes required to fabricate pressure vessels, including cutting, forming, welding, machining, and testing, as well as suggestions on controlling costs. Each chapter provides a complete description of a specific fabrication process and details its characteristics and requirements. Alongside the accessible and practical text, you’ll find equations, charts, copious illustrations, and other study aids designed to assist the reader in the real-world implementation of the concepts discussed within the book. You’ll find numerous appendices that include weld symbols, volume and area equations, pipe and tube dimensions, weld deposition rates, lifting shackle data, and more. In addition to detailed discussions of cutting, machining, welding, and post-weld heat treatments, readers will also benefit from the inclusion of: A thorough introduction to construction materials, including both ferrous and nonferrous alloys An exploration of layout, including projection and triangulation, material thickness and bending allowance, angles and channels, and marking conventions A treatment of material forming, including bending versus three-dimensional forming, plastic theory, forming limits, brake forming, roll forming, and tolerances Practical discussions of fabrication, including weld preparation, forming, vessel fit up and assembly, correction of distortion, and transportation of vessels Perfect for new and established engineers, designers, and procurement personnel working with process equipment or in the fabrication field, Fabrication of Metallic Pressure Vessels will also earn a place in the libraries of students in engineering programs seeking a one-stop resource for the fabrication of pressure vessels.







Pressure Vessel related interview Questions and Answers


Book Description

This book has been specifically designed for aspiring engineers, technicians, and professionals who are seeking to pursue a career in the field of pressure vessel technology. In this book, you will find an extensive collection of the most commonly asked interview questions, along with their answers. The questions are designed to test your understanding of the fundamental concepts of pressure vessels and their applications. The answers, on the other hand, provide a clear and concise explanation of the key aspects of pressure vessels. I have drawn upon my years of experience in the industry and have shared my knowledge on the best approaches to handle different interview scenarios. Overall, this book is an indispensable resource for anyone looking to secure a position in the field of pressure vessel technology. So, if you want to ace your pressure vessel interview and take your career to the next level, this book is a must-read.




60 Excellent Inventions in Metal Forming


Book Description

60 novel approaches in metal forming are presented and explained in detail. Contributions from acknowledged international scientists representing the state-of-art in metal forming open a general view on recent results and a clear view on demands for new research initiatives.




Pressure Oscillation in Biomedical Diagnostics and Therapy


Book Description

Complete and comprehensive reference on the principles of diagnostic and therapeutic techniques using pressure oscillation Pressure Oscillation in Biomedical Diagnostics and Therapy presents key findings in imaging, diagnostics, and therapies using high and low frequency pressure waves in a concise and easy-to-understand way, focusing primarily on the cardiovascular and pulmonary systems that utilize acoustics (mechanical wave motion). The work provides basic background in relevant acoustic theory as well as specific technical information associated with modern medical applications. Low frequency acoustics (pressure oscillation) and some aspects of ultrasound (radiation force) are also reviewed. The principles in the work can be extended to include other areas relating to materials and metal diagnostics. To allow for maximum reader comprehension regardless of current expertise on the subject, each chapter includes a brief history, current developments, and practical applications of the topic covered within. Furthermore, all chapters are based on engineering and physiological principles to deliver practical technologies. Sample topics covered in the work include: Fundamental principles of pressure oscillation (PO), discussing the basic principles of pressure oscillation and how they can be formulated into mathematical equations PO in imaging techniques, discussing the basic principles of converting pressure oscillation to a tool in biomedical imaging Lung mechanics, discussing how each part of the lung is associated with various diseases and how PO can target these parts Asthma, discussing the basic concepts of asthma, the importance of airway smooth muscle (ASM), and dynamic behavior of ASM Pressure Oscillation in Biomedical Diagnostics and Therapy links pressure oscillation (PO) and biomedical diagnostics and therapy for scholars and practitioners. It is an essential resource for all professionals who wish to be on the cutting edge of treating lung diseases such as obstructive sleep apnea, asthma, and respiratory distress syndrome.




Pressure Vessel Design Manual


Book Description

Pressure vessels are closed containers designed to hold gases or liquids at a pressure substantially different from the ambient pressure. They have a variety of applications in industry, including in oil refineries, nuclear reactors, vehicle airbrake reservoirs, and more. The pressure differential with such vessels is dangerous, and due to the risk of accident and fatality around their use, the design, manufacture, operation and inspection of pressure vessels is regulated by engineering authorities and guided by legal codes and standards. Pressure Vessel Design Manual is a solutions-focused guide to the many problems and technical challenges involved in the design of pressure vessels to match stringent standards and codes. It brings together otherwise scattered information and explanations into one easy-to-use resource to minimize research and take readers from problem to solution in the most direct manner possible. - Covers almost all problems that a working pressure vessel designer can expect to face, with 50+ step-by-step design procedures including a wealth of equations, explanations and data - Internationally recognized, widely referenced and trusted, with 20+ years of use in over 30 countries making it an accepted industry standard guide - Now revised with up-to-date ASME, ASCE and API regulatory code information, and dual unit coverage for increased ease of international use




Process Equipment Design


Book Description

A complete overview and considerations in process equipment design Handling and storage of large quantities of materials is crucial to the chemical engineering of a wide variety of products. Process Equipment Design explores in great detail the design and construction of the containers – or vessels – required to perform any given task within this field. The book provides an introduction to the factors that influence the design of vessels and the various types of vessels, which are typically classified according to their geometry. The text then delves into design and other considerations for the construction of each type of vessel, providing in the process a complete overview of process equipment design.




GB 150.1-2011 English Translation of Chinese Standard


Book Description

1.1 This standard specifies the construction requirements of metal pressure vessels (hereinafter referred to as "Vessels"). This standard specifies the general requirements for the materials, design, fabrication, inspection and testing, and acceptance of metal pressure vessels (hereinafter referred to as “Vessels”). 1.2 Applicable design pressure of this Standard 1.2.1 For steel vessels, the design pressure shall not exceed 35MPa; 1.2.2 For vessels made of other metal materials, the applicable design pressure shall be determined according to the corresponding reference standards. 1.3 Applicable design temperature range of this Standard 1.3.1 Design temperature range: -269℃~900℃. 1.3.2 For steel vessels, the design temperature shall not exceed the allowable operating temperature range of the materials listed in GB 150.2 1.3.3 For vessels made of other metal materials, the design temperature shall be determined according to the allowable operating temperature of the materials listed in the corresponding reference standards of this Part. 1.4 Applicable structure forms of this Standard 1.4.1 The structure forms of the steel vessels to which this Standard is applicable shall be in accordance with the corresponding provisions of this Part and GB 150.2 ~ GB 150.4. 1.4.2 As for the vessels with specific structures and the vessels made of aluminum, titanium, copper, nickel and nickel alloy, as well as zirconium to which this Standard is applicable, the structure forms and applicable scope shall meet the corresponding requirements of the following standards: a) GB 151 Tubular Heat Exchangers; b) GB 12337 Steel Spherical Tanks; c) JB/T 4731 Steel Horizontal Vessels on Saddle Support; d) JB/T 4710 Steel Vertical Vessels Supported by Skirt; e) JB/T 4734 Aluminim Welded Vessels; f) JB/T 4745 Titanium Welded Vessels; g) JB/T 4755 Copper Pressure Vessels; h) JB/T 4756 Nickel and Nickel Alloy Pressure Vessels; i) NB/T 47011 Zirconium Pressure Vessels. 1.5 The following vessels are not within the applicable scope of this Standard: a) Vessels with design pressure lower than 0.1MPa and vacuum degree lower than 0.02MPa; b) Vessels under "Supervision Regulation on Safety Technology for Transportable Pressure Vessel"; c) Among equipment, the pressure chambers (such as pump casing, outer casing of compressors, outer casing of turbines, hydraulic cylinders etc.) which can be its own system or as components in swiveling or reciprocating movement machinery; d) Vessels subject to the neutron radiation damage failure risk in nuclear power plants. e) Vessels heated by direct flame; f) Vessels with inner diameter (for non-circular sections, refers to the maximum geometric dimensions of the inner boundaries of the sections, such as: diagonals of rectangles and major axes of ellipses) less than 150mm; g) Enamelled vessels and the vessels with other national standards or professional standards in the refrigeration and air conditioning industry. 1.6 Vessels scope 1.6.1 Connection between the vessel and the external pipe: a) The groove end face of the first pass of girth joints with welded connection; b) The first threaded connector end surface of screwed joint; c) The sealing surface of the first flange with flanged connection; d) The first sealing surface of special connecting piece or pipe fittings connection. 1.6.2 Bearing headers, flat covers and their fasteners of connection pipe, manhole and handhole, etc. 1.6.3 Attachment welds between non-pressure components and pressure components. 1.6.4 Non-pressure components such as support and skirt directly connected to the vessels. 1.6.5 Excessive pressure relief device of vessel (see Appendix B).




Safety Design for Space Systems


Book Description

Progress in space safety lies in the acceptance of safety design and engineering as an integral part of the design and implementation process for new space systems. Safety must be seen as the principle design driver of utmost importance from the outset of the design process, which is only achieved through a culture change that moves all stakeholders toward front-end loaded safety concepts. This approach entails a common understanding and mastering of basic principles of safety design for space systems at all levels of the program organisation. Fully supported by the International Association for the Advancement of Space Safety (IAASS), written by the leading figures in the industry, with frontline experience from projects ranging from the Apollo missions, Skylab, the Space Shuttle and the International Space Station, this book provides a comprehensive reference for aerospace engineers in industry. It addresses each of the key elements that impact on space systems safety, including: the space environment (natural and induced); human physiology in space; human rating factors; emergency capabilities; launch propellants and oxidizer systems; life support systems; battery and fuel cell safety; nuclear power generators (NPG) safety; habitat activities; fire protection; safety-critical software development; collision avoidance systems design; operations and on-orbit maintenance. - The only comprehensive space systems safety reference, its must-have status within space agencies and suppliers, technical and aerospace libraries is practically guaranteed - Written by the leading figures in the industry from NASA, ESA, JAXA, (et cetera), with frontline experience from projects ranging from the Apollo missions, Skylab, the Space Shuttle, small and large satellite systems, and the International Space Station - Superb quality information for engineers, programme managers, suppliers and aerospace technologists; fully supported by the IAASS (International Association for the Advancement of Space Safety)




Ultra High Pressure Treatment of Foods


Book Description

During the past decade, consumer demand for convenient, fresh-like, safe, high-quality food products has grown. The food industry has responded by applying a number of new technologies including high hydrostatic pressure for food processing and preservation. In addition, food scientists have demonstrated the feasibility of industrial-scale high pressure processing. This technology is of specific interest to the food industry because it provides an attractive alternative to conventional methods of thermal processing, which often produce undesirable changes in foods and hamper the balance between high quality (color, flavor, and functionality) and safety. In addition, it offers opportunities for creating new ingredients and products because of the specific actions of high pressure on bio logical materials and food constituents. It allows food scientists to redesign exist ing processes and to create entirely new ones using high pressure technology alone or in combination with conventional processes (e. g. , pressure-temperature combinations ). Researchers have investigated high pressure processing for the past century. Scientists such as Hite and Bridgman did pioneering work at the turn of the 20th century. Then during the 1980s and 1990s, there was a large effort to investigate the effects of high pressure on biological materials, particularly foods. The initial research activities in the late 1980s and early 1990s focused on exploratory activ ities in the food area.