| Author: |
Guo Jiang
|
| Title: |
Frontiers in Ultra-Precision Machining
|
| Publisher: |
Basel, : MDPI - Multidisciplinary Digital Publishing Institute, 2022 |
| Physical description: |
1 online resource (246 p.) |
| Topical subject: |
History of engineering and technology |
| |
Technology: general issues |
| Uncontrolled subject: |
Al/Ni multilayers |
| |
aluminum |
| |
atmospheric pressure plasma jet |
| |
atom probe tomography (APT) |
| |
benchmark coincidence |
| |
blisk |
| |
Bouc-Wen model |
| |
cluster effect |
| |
combined repairing process |
| |
computer-controlled optical surfacing |
| |
continuous phase plate |
| |
crystal orientation |
| |
cutting forces |
| |
cutting strategy |
| |
data processing |
| |
data-dependent systems |
| |
diamond grinding |
| |
diamond tool |
| |
dwell time algorithm |
| |
dynamic modeling |
| |
dynamic switching probability strategy |
| |
eccentricity |
| |
electrical properties |
| |
electrochemical discharge machining (ECDM) |
| |
electrode wear ratio (EWR) |
| |
electrorheological polishing |
| |
elementary approximation |
| |
evolution law |
| |
ferrous metal |
| |
flange |
| |
flexible grinding |
| |
flower pollination algorithm |
| |
focused ion beam (FIB) |
| |
fused silica |
| |
high accuracy and efficiency |
| |
high aspect ratio |
| |
high-shear low-pressure |
| |
integrated electrode |
| |
ion beam sputtering |
| |
lift-out |
| |
lubricant |
| |
machining parameters |
| |
machining stability |
| |
magnetorheological removing method |
| |
material removal rate (MRR) |
| |
microlens array |
| |
microstructured surfaces |
| |
molecular dynamics |
| |
morphology evolution |
| |
multi-physics coupling simulation |
| |
n/a |
| |
Nano-ZrO2 ceramics |
| |
narrow channel |
| |
optimization |
| |
overcut (OC) |
| |
parameter identification |
| |
piezoelectric actuator |
| |
piezoelectric hysteresis |
| |
polar microstructures |
| |
polishing tool |
| |
removal function |
| |
reversal method |
| |
roughness |
| |
shear thickening fluid |
| |
single crystal silicon |
| |
single-point diamond turning |
| |
single-wedge |
| |
small-scale damage |
| |
spherical shell |
| |
subsurface damage |
| |
surface characterization |
| |
surface quality |
| |
surface residual material |
| |
surface topography |
| |
surface topography variation |
| |
thin-walled part |
| |
three-dimensional elliptical vibration cutting |
| |
three-dimensional surface roughness |
| |
tool material |
| |
tool servo diamond cutting |
| |
ultra-precision grinding |
| |
ultra-precision machining |
| |
vibration-assisted electrochemical machining (ECM) |
| |
wall-thickness |
| Person (second resp.): |
WangChunjin |
| |
KangChengwei |
| |
GuoJiang |
| Summary, etc: |
Ultra-precision machining is a multi-disciplinary research area that is an important branch of manufacturing technology. It targets achieving ultra-precision form or surface roughness accuracy, forming the backbone and support of today's innovative technology industries in aerospace, semiconductors, optics, telecommunications, energy, etc. The increasing demand for components with ultra-precision accuracy has stimulated the development of ultra-precision machining technology in recent decades. Accordingly, this Special Issue includes reviews and regular research papers on the frontiers of ultra-precision machining and will serve as a platform for the communication of the latest development and innovations of ultra-precision machining technologies. |
| Preferred title for the work: |
Frontiers in Ultra-Precision Machining |
|
| Format: |
Language material  |
| Bibliographic level |
Monograph |
| Language: |
English |
| Record Nr.: | 9910566486003321 |
|
| You will find it: | Univ. Federico II |
| Opac: |
Check copies here |
