File Size: 19.54 Mb
Description
The development of precision engineering has greatly increased our living standards. High-precision manufacturing not only offers quality and reliability for conventional products but also opens
windows to entirely new products at the standard, meso-, and microscale with new features such as mechatronics, high density function, and high performance.
Precision engineering involves development at the forefront of current technology. Current advanced technology products are dependent on high-precision manufacturing processes, machines,
control technologies, and even nanotechnology. Achieving ultrahigh precision in the manufacture of extremely small devices opens up prospects in several diverse and futuristic fi elds such as massive computing power, biomedical devices, global personal communication devices, and high-resolution optical devices. Precision engineering is a multidisciplinary fi eld that includes machine tool design, materials, machining processes with novel manufacturing methods, metrology, sensors and actuators,
microsystems, biomedical applications, and other relevant fi elds. Precision engineering requires an in-depth understanding of most physical phenomena within the previous disciplines and their effects at the micro- and nanoscale.
With the current trend toward highest precision micromachining and assembly systems based on continuous miniaturization and functional integration of products, application areas with enormous
market growth are extended to automotive goods, optoelectronics, biomedicine, microchemistry, and consumer goods. Microelectronics needs mechanical interfaces, electrical and optical connections with smaller geometries, and structures and tolerances down to nanometers.
windows to entirely new products at the standard, meso-, and microscale with new features such as mechatronics, high density function, and high performance.
Precision engineering involves development at the forefront of current technology. Current advanced technology products are dependent on high-precision manufacturing processes, machines,
control technologies, and even nanotechnology. Achieving ultrahigh precision in the manufacture of extremely small devices opens up prospects in several diverse and futuristic fi elds such as massive computing power, biomedical devices, global personal communication devices, and high-resolution optical devices. Precision engineering is a multidisciplinary fi eld that includes machine tool design, materials, machining processes with novel manufacturing methods, metrology, sensors and actuators,
microsystems, biomedical applications, and other relevant fi elds. Precision engineering requires an in-depth understanding of most physical phenomena within the previous disciplines and their effects at the micro- and nanoscale.
With the current trend toward highest precision micromachining and assembly systems based on continuous miniaturization and functional integration of products, application areas with enormous
market growth are extended to automotive goods, optoelectronics, biomedicine, microchemistry, and consumer goods. Microelectronics needs mechanical interfaces, electrical and optical connections with smaller geometries, and structures and tolerances down to nanometers.
Content:-
PrefaceAcknowledgments
Editor
Contributors
Contributor Profiles
Chapter 1: Introduction to Precision Engineering
Chapter 2: Motion Errors
Chapter 3: Thermal Problems in Machine Tools Design and Operation
Chapter 4: Design Strategies and Machine Key-Components
Chapter 5: Introduction to Parallel Kinematic Machines
Chapter 6: Precision Control
Chapter 7: Actuators, Transmission, and Sensors
Chapter 8: Current Issues in Error Modeling—3D Volumetric Positioning Errors
Index
Author Details
"Samir Mekid"
You May Also Like These E-Books:-
No comments:
Post a Comment