Basics of Mechanical Engineering systematically develops the concepts and principles essential for understanding engineering thermodynamics, mechanics and strength of materials. This book is meant for first year B. Tech students of various technical universities. It will also be helpful for candidates preparing for various competitive examinations.

Written with the first year engineering students of undergraduate level in mind, the well-designed textbook, now in its Third Edition, explains the fundamentals of mechanical engineering in the area of thermodynamics, mechanics, theory of machines, strength of materials and fluid dynamics. As these subjects form a basic part of an engineer’s education, this text is admirably suited to meet the needs of the common course in mechanical engineering prescribed in the curricula of almost all branches of engineering. This revised edition includes a new chapter on ‘Fluid Dynamics’ to meet the course requirement. Key Features • Presents an introduction to basic mechanical engineering topics required by all engineering students in their studies. • Includes a series of objective type question (True and False, Fill in the Blanks and Multiple Choice Questions) with explanatory answers to help students in preparing for competitive examinations. • Provides a large number of solved problems culled from the latest university and competitive examination papers which help in understanding theory.

Focusing on optimal design, this book covers such topics as fracture, mechanics, bolted joints, composite materials, weld components and fatigue testing. Computer techniques are featured throughout the book and there is a whole chapter on CAD/CAM.

The traditional approach to teaching mechanical engineering has been to cover either mechanics or thermofluid mechanics. In response to the growing trend toward more general modules, Foundations of Mechanical Engineering provides a unified approach to teaching the basic mechanical engineering topics of mechanics, the mechanics of solids, and thermofluid mechanics.Each chapter provides a systematic approach to the subject matter and begins with a list of aims and concludes with a summary of the key equations introduced in that chapter. Copious worked examples illustrate the correct approach to problem solving, and outline solutions for all of the end-of-chapter problems let students check their own work. The authors have judiciously minimized the mathematical content and where necessary, introduce the fundamentals through diagrams and graphical representations.With complete basic coverage of both statics and dynamics, the mechanics of solids, fluid flow, and heat transfer, Foundations of Mechanical Engineering forms and ideal text for first-year mechanical engineering students.

Explains the fundamentals of mechanical engineering for the undergraduate students of all branches of engineering. Coverage includes machine tool and fabrication processes; thermodynamics, IC engines and steam turbines; hydraulic turbines and pumps; refrigeration and air-conditioning; power transmission methods and devices; and stresses, strain, shear force and bending moment diagrams.

Engineering Fundamentals is designed to meet the latest course requirements, and brings together the essential material from Roger Timings' previous engineering texts: Fundamentals of Mechanical Engineering, Fundamentals of Engineering, Basic Engineering Technology and General Engineering. A highly readable text is supported by numerous illustrations, learning objectives and exercises at the end of each chapter, making Engineering Fundamentals a complete student-focused course that is ideal for classroom, workshop and independent study.

This introductory book covers the most fundamental aspects of linear vibration analysis for mechanical engineering students and engineers. Consisting of five major topics, each has its own chapter and is aligned with five major objectives of the book. It starts from a concise, rigorous and yet accessible introduction to Lagrangian dynamics as a tool for obtaining the governing equation(s) for a system, the starting point of vibration analysis. The second topic introduces mathematical tools for vibration analyses for single degree-of-freedom systems. In the process, every example includes a section Exploring the Solution with MATLAB. This is intended to develop student's affinity to symbolic calculations, and to encourage curiosity-driven explorations. The third topic introduces the lumped-parameter modeling to convert simple engineering structures into models of equivalent masses and springs. The fourth topic introduces mathematical tools for general multiple degrees of freedom systems, with many examples suitable for hand calculation, and a few computer-aided examples that bridges the lumped-parameter models and continuous systems. The last topic introduces the finite element method as a jumping point for students to understand the theory and the use of commercial software for vibration analysis of real-world structures.