The use of active materials for machining processes: A review

International Journal of Machine Tools and Manufacture

Volumn 47, Issue 15, 2007, Pages 2189-2206

  Park, Gyuhae ^a   Bement, Matthew T ^a   Hartman, Daniel A ^a   Smith, Ronald E ^a   Farrar, Charles R ^a  

^a LOS ALAMOS NATIONAL LABORATORY   (United States)

Author keywords

Active materials; Fast tool servo; Magnetorheological and electrorheological fluids; Magnetostrictive materials; Piezoelectric materials

Indexed keywords

ELECTRORHEOLOGICAL FLUIDS; MACHINE TOOLS; MACHINING; MAGNETORESISTANCE;

ACTIVE MATERIALS; FAST TOOL SERVO; MAGNETOSTRICTIVE MATERIALS;

PIEZOELECTRIC MATERIALS;

EID: 35348873925     PISSN: 08906955     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijmachtools.2007.06.002     Document Type: Review

References (147)

1. Schellekens P., Rosielle N., Vermeulen H., Vermeulen M., Wetzels S., and Pril W. Design for precision: current status and trends. Annals of the CIRP 47 2 (1997) 557-586
2. Liang S.Y., Hecker R.L., and Landers R.G. Machining process monitoring and control: the state-of-the-art. ASME Journal of Manufacturing Science and Engineering 126 5 (2004) 297-310
3. Srinivasan S., and McFarland M. Smart Structures: Analysis and Design (2001), Cambridge University Press, Cambridge
4. Chopra I. Review of state of art of smart structures and integrated systems. AIAA Journal 40 11 (2002) 2145-2187
5. D.J. Inman, Smart materials in damage detection and prognosis, in: Proceedings of the Fifth International Conference on Damage Assessment of Structures, Southampton, UK, 2003, pp. 3-16.
6. Sodano H.A., Inman D.J., and Park G. A review of power harvesting from vibration using piezoelectric materials. The Shock and Vibration Digest 36 (2004) 197-205
7. Hurlebaus S., and Gaul L. Smart structure dynamics. Mechanical Systems and Signal Processing 20 (2006) 255-281
8. Crawley E.F., and de Luis J. Use of piezoelectric actuators as elements of intelligent structures. AIAA Journal 25 10 (1987) 1373-1385
9. Crawley E., and Anderson E. Detailed models of piezoceramic actuation of beams. Journal of Intelligent Materials and Structures 1 1 (1990) 4-25
10. Hagood N.W., Chung W.H., and von Flotow A. Modeling of piezoelectric actuator dynamics for active structural control. Journal of Intelligent Materials Systems and Structures 1 (1990) 327-354
11. Smits J., and Choi W. The constituent equations of heterogeneous bimorphs. IEEE Transactions on Ultrasonic, Ferroelectrics and Frequency Control 38 3 (1991) 256-270
12. Sirohi J., and Chopra I. Fundamental behavior of piezoceramic sheet actuators. Journal of Intelligent Material Systems and Structures 11 1 (2000) 47-61
13. Sirohi J., and Chopra I. Fundamental understanding of piezoelectric strain sensors. Journal of Intelligent Material Systems and Structures 11 4 (2000) 246-257
14. Niezrecki C., Brei D., Balakrishnan S., and Moskalik A. Piezoelectric actuation: state of the art. The Shock and Vibration Digest 33 4 (2001) 269-280
15. Gandhi M.V., and Thompson B.S. Smart Materials and Structures (1994), Chapman and Hall, London
16. Ikeda T. Fundamentals of Piezoelectricity (1996), Oxford Press
17. Banks H.T., Smith R.C., and Wang Y. Smart Materials and Structures: Modeling, Estimation and Control (1996), Wiley, Chichester
18. Culshaw B. Smart Structures and Materials (1996), Artech House
19. Clark R.L., Saunders W.R., and Gibbs G.P. Adaptive Structures: Dynamics and Control (1998), Wiley, Chichester
20. Patterson S.R., and Magrab E.B. The design and testing of a fast tool servo for diamond turning. Precision Engineering 7 3 (1985) 123-128
21. Kohno T., Okazaki Y., Ozawa N., Mitui K., and Omoda M. In-process measurement and a workpiece-referred form accuracy control system (WORFAC): concept of the method and preliminary experiment. Precision Engineering 11 1 (1989) 9-14
22. Okazaki Y. A micro-positioning tool post using a piezoelectric actuator for diamond turning machines. Precision Engineering 12 3 (1990) 151-156
23. P.J. Falter, Diamond turning of nonrotationally symmetric surfaces, PhD Dissertation, North Carolina State University, 1990.
24. R.J. Fornaro, K.P. Garrard, L.W. Taylor, Architecture and algorithms for computer control of high precision machine tools, Proceedings of the Fifth Annual ASPE Conference 2 (1990) 27-30.
25. Dow T.A., Miller M.H., and Falter P.J. Application of a fast tool servo for diamond turning of nonrotationally symmetric surfaces. Precision Engineering 13 4 (1991) 243-250
26. Miller M.H., Garrard K.P., Dow T.A., and Taylor L.W. A controller architecture for integrating a fast tool servo into a diamond turning machine. Precision Engineering 16 1 (1994) 42-48
27. Moorefield G.M., Garrard K.P., Falter K.J., Taylor L.W., and Dow T.A. Generation of rotationally asymmetric optical surfaces using a fast tool servo. Proceedings of the Ninth Annual ASPE Meeting 10 (1994) 45-48
28. Jared B.H., Dow T.A., Garrard K.P., Moorefield G.M., Barnes C., Day R.D., Hatch D.J., Salzer L.J., and Rivera G. Fabrication of hydrodynamic instability targets. Fusion Technology 31 (1997) 501-503
29. Garrard K., Bruegge T., Hoffman J., Dow T., and Sohn A. Design tools for freeform optics. Proceedings of SPIE-The International Society for Optical Engineering 5874 (2005) 1-11
30. Cuttino J.F., Miller A.C., and Schinstock D.E. Performance optimization of a fast tool servo for single-point diamond turning machines. IEEE/ASME Transactions on Mechatronics 4 2 (1999) 169-179
31. Kim H.S., and Kim E.J. Feed-forward control of fast tool servo for real-time correction of spindle error in diamond turning of flat surfaces. International Journal of Machine Tools & Manufacture 43 (2003) 1177-1183
32. Kim H.S., Kim E.J., and Song B.S. Diamond turning of large off-axis aspheric mirrors using a fast tool servo with on-machine measurement. Journal of Materials Processing Technology 146 (2004) 349-355
33. Crudele M., and Kurfess T.R. Implementation of a fast tool servo with repetitive control for diamond turning. Mechatronics 13 (2003) 243-257
34. Rasmussen J.D., Tsao T.C., Hanson R.D., and Kapoor S.G. Dynamic variable depth of cut machining using piezoelectric actuators. International Journal of Machine Tools and Manufacture 34 3 (1994) 379-392
35. Kim J.D., and Nam S.R. Development of a micro-depth control system for an ultra-precision lathe using a piezoelectric actuator. International Journal of Machine Tools & Manufacture 37 4 (1997) 495-509
36. Kim J.D., and Kim D.S. Development of a micro-depth control system for an ultra-precision lathe using a piezoelectric actuator. International Journal of Machine Tools & Manufacture 38 (1998) 1305-1322
37. Dosch J.J., Inman D.J., and Garcia E. A self sensing piezoelectric actuator for collocated control. Journal of Intelligent Material Systems and Structures 3 (1992) 166-185
38. Gao W., Araki T., Kiyono S., Okazaki Y., and Yamanaka M. Precision nano-fabrication and evaluation of a large area sinusoidal grid surface for a surface encoder. Precision Engineering 27 (2003) 289-298
39. Lee C.W., and Kim S.W. An ultraprecision stage for alignment of wafers in advanced microlithography. Precision Engineering 21 (1997) 113-122
40. Ku S.S., Larsen G., and Cetinkunt S. Fast tool servo control for ultra-precision machining at extremely low feed rates. Mechatronics 8 (1998) 381-393
41. Pahk H.J., Lee S.D., and Park J.H. Ultra precision positioning system for servo motor-piezo actuator using the dual servo loop and digital filter implementation. International Journal of Machine Tools & Manufacture 41 (2001) 51-63
42. B.S. Kim, J. Li, T.C. Tsao, Control of a dual stage actuator system for noncircular cam turning process, in: Proceedings of the American Control Conference, Arlington, VA, 2001, pp. 2549-2554.
43. R. Krishnamoorthy, C.Y. Lin, T.C. Tsao, Design and control of a dual stage fast tool servo for precision machining, in: Proceedings of the 2004 IEEE International Conference on Control Applications, 2004, pp. 742-747.
44. Elfizy A.T., Bone G.M., and Elbestawi M.A. Design and control of a dual-stage feed drive. International Journal of Machine Tools & Manufacture 45 (2004) 153-165
45. Elfizy A.T., Bone G.M., and Elbestawi M.A. Model-based controller design for machine tool direct feed drives. International Journal of Machine Tools & Manufacture 44 (2004) 465-477
46. Zhu W.H., Jun M.B., and Altintas Y. A fast tool servo design for precision turning of shafts on conventional CNC lathes. International Journal of Machine Tools & Manufacture 41 (2001) 953-965
47. Woronko A., Huang J., and Altintas Y. Piezoelectric tool actuator for precision machining on conventional CNC turning centers. Precision Engineering 27 (2003) 335-345
48. Babitsky V.I., Kalashnikov A.N., Meadows A., and Wijesundara A.A.H.P. Ultrasonically assisted turning of aviation materials. Journal of Materials Processing Technology 132 (2003) 157-167
49. Astashev V.K., and Babitsky V.I. Ultrasonic cutting as a nonlinear (vibro-impact) process. Ultrsonics 36 (1998) 89-96
50. Thoe T.B., Aspinwall D.K., and Wise M.L.H. Review on ultrasonic machining. International Journal of Machine Tools & Manufacture 38 4 (1997) 239-255
51. Babitsky V.I., Kalashnikov A.N., and Molodtsov F.V. Autoresonant control of ultrasonically assisted cutting. Mechatronics 14 (2004) 91-114
52. Du Z.C., Yang J.G., and Yan J.P. Vibration characteristics of piezoelectric micro displacement actuator driven directly for ultrasonic machining. Key Engineering Materials 259-260 (2004) 609-614
53. Zhong Z.W., and Lin G. Diamond turning of a metal matrix composite with ultrasonic vibration. Materials and Manufacturing Processes 20 (2005) 727-735
54. Xu W.L., and Han L. Piezoelectric actuator based active error compensation of precision machining. Measurement Sciences and Technology 10 (1999) 106-111
55. Fabris N.S., and D'Souza A.F. Nonlinear stability analysis of chatter in metal cutting. Transaction of ASME Journal of Engineering for Industry 96 (1974) 670-675
56. Jemielniak K., and Widota A. Numerical simulation of nonlinear chatter vibration in turning. International Journal of Machine Tools & Manufacture 29 (1989) 239-247
57. Marui E., Hashimoto M., and Kato S. Regenerative chatter vibration occurring in turning with different side cutting edge angles. Journal of Engineering for Industry 117 (1995) 551-558
58. Chiou R.Y., and Liang S.Y. Chatter stability of a slender cutting tool in turning with tool wear effect. International Journal of Machine Tools & Manufacture 38 (1998) 315-327
59. Martinez D.R., Hinnerichs T.D., and Redmond J.M. Vibration control for precision manufacturing using piezoelectric actuators. Journal of Intelligent Material Systems and Structures 7 (1996) 182-191
60. Eshete Z., and Zhang G. In-process machine tool vibration cancellation using PMN actuators. Proceedings of the SPIE-The International Society for Optical Engineering 2911 (1996) 63-70
61. Choudhury S.K., Goudimenko N.N., and Kudinov V.A. On-line control of machine tool vibration in turning. International Journal of Machine Tools & Manufacture 37 (1997) 801-811
62. Nagaya K., Yamazaki H., and Kashimoto H. Control of micro-vibrations of a machine head by using piezoelectric actuators. International Journal of Applied Electromagnetics and Mechanics 8 (1997) 315-328
63. Mayhan P., Srinivasan K., Watechagit S., and Washington G. Dynamic modeling and controller design for a piezoelectric actuation system used for machine tool control. Journal of Intelligent Material Systems and Structures 11 (2000) 771-780
64. Yan W.Y., and Al-Jumaily A.M. Feasibility of using an active actuator for two-dimensional vibration abatement in a turning process. Journal of Multi-Body Dynamics 216 (2002) 335-342
65. Chiou C.H., Hong M.S., and Ehmann K.F. The feasibility of eigenstructure assignment for machining chatter control. International Journal of Machine Tools & Manufacture 43 (2003) 1603-1620
66. A. Harms, B. Denkena, N. Lhermet, Tool adaptor for active vibration control in turning operation, in: Proceedings of Ninth International Conference on New Actuators, Bremen, Germany, 2004, pp. 694-697.
67. Rashid M.K. Smart actuator stiffness and switching frequency in suppression of vibration of a cutting tool. Smart Materials and Structures 13 (2005) 478-486
68. Fung E.H.K., and Yang S.M. A new method for roundness control in taper turning using FCC techniques. Journal of Manufacturing Science and Engineering 123 (2001) 567-575
69. J.C. Pan, C.Y. Su, Chatter suppression with adaptive control in turning metal via application of piezoactuator, in: Proceedings of the 40th IEEE Conference on Decision and Control, Orlando, FL, 2001, pp. 2436-2441.
70. J. Wang, C.Y. Su, Two degree-of-freedom modeling and robust chatter control in metal cutting by piezoelectricity, in: Proceedings of the American Control Conference, Denver, CO, 2003, pp. 3044-3048.
71. Dohner J.L., Lauffer J.P., Hinnerichs T.D., Shankar N., Regelbrugge M., Kwan C.M., Xu R., Winterbaur B., and Bridger K. Mitigation of chatter instabilities in milling by active structural control. Journal of Sound and Vibrations 269 (2004) 197-211
72. Tarng Y.S., Kao J.Y., and Lee E.C. Chatter suppression in turning operations with a tuned vibration absorber. Journal of Materials Processing Technology 105 (2000) 55-60
73. Lee E.C., Nian C.Y., and Tarng Y.S. Design of a dynamic vibration absorber against vibrations in turning operation. Journal of Materials Processing Technology 108 (2001) 278-285
74. L. Petersson, L. Hakansson, I. Claesson, S. Olsson, Active control of machine-tool vibration in a CNC lathe based on an active tool holder shank with embedded piezoceramic actuators, in: Proceedings of Eighth International Congress on Sound and Vibrations, HongKong, 2001, pp. 301-308.
75. Zhang Y., and Sims N.D. Milling workpiece chatter avoidance using piezoelectric active damping: a feasibility study. Smart Materials and Structures 14 (2004) 65-70
76. Sims N.D., Bayly P.V., and Young K.A. Piezoelectric sensors and actuators for milling tool stability lobes. Journal of Sound and Vibrations 281 (2005) 743-762
77. P. Barney, J. Redmond, D. Smith, Characteristics of self-sensing actuation for active control, in: Proceedings of the International Modal Analysis Conference, 1997, pp. 739-744.
78. Browning D.R., Golioto I., and Thompson N.B. Active chatter control system for long-overhang boring bars. Proceedings of the SPIE-The International Society for Optical Engineering 3044 (1997) 270-280
79. Chiu W.M., and Chan K.W. Design and testing of piezoelectric actuator-controlled boring bar for active compensation of cutting force induced errors. International Journal of Production Economics 51 (1997) 135-148
80. Chiu W.M., Lam F.W., and Gao D. An overhung boring bar servo system for on-line correction of machining error. Journal of Materials Processing Technology 122 (2002) 286-292
81. Gao D., Yao Y.X., Chiu W.M., and Lam F.W. Accuracy enhancement of a small overhung boring bar servo system by real-time error compensation. Precision Engineering 26 (2002) 456-459
82. Hanson R.D., and Tsao T.C. Reducing cutting force induced bore cylindricity errors by learning control and variable depth of cut machining. Journal of Manufacturing Science and Engineering 120 (1998) 547-554
83. Katsuki A., Onikura H., Sajima T., Takei T., and Thiele D. Development of high-performance laser-guided deep-hole boring tool: optimal determination of reference origin for precise guiding. Precision Engineering 24 (2000) 9-14
84. O'Neal G.P., Min B.K., Pasek Z.J., and Korean Y. Integrated structural/control design of micro-positioner for boring bar tool insert. Journal of Intelligent Material Systems and Structures 12 (2001) 617-627
85. O'Neal G.P., Min B.K., Li C.J., Pasek Z.J., Korean Y., and Szuba P. Precision piezoelectric micro-positioner for line boring bar tool insert. Proceedings of ASME International Mechanical Engineering Congress and Exposition, Vibration and Noise Control DSC 65 (1998) 99-106
86. Koren Y., Pasek Z., and Szuba P. Design of a precision, agile line boring station. CIRP Annals-Manufacturing Technology 48 1 (1999) 313-316
87. Min B.K., O'Neal G.P., Koran Y., and Pasek Z. A smart boring tool for process control. Mechatronics 12 (2002) 1097-1114
88. Chang S.H., and Li S.C. A high resolution long travel friction-drive micropositioner with programmable step size. Review of Scientific Instruments 70 6 (1999) 1-7
89. Koratkar N.A., and Chopra I. Design, fabrication and testing of a mach scaled rotor model with trailing-edge flaps. Annual Forum Proceedings-American Helicopter Society 1 (1999) 558-578
90. Lee T., and Chopra I. Development and validation of a refined piezostack-actuated trailing edge flap actuator for a helicopter rotor. Proceedings of the SPIE-The International Society for Optical Engineering 3668 (1999) 22-36
91. Le Letty R., Claeyssen F., Lhermet N., and Bouchilloux P. A new amplified piezoelectric actuator for precise positioning and active damping. Proceedings of the SPIE-The International Society for Optical Engineering 3041 (1997) 496-504
92. Pokines B.J., and Garcia E. A smart material microamplification mechanism fabricated using LIGA. Smart Materials and Structures 7 (1998) 105-112
93. Chang S.H., and Du B.C. A precision piezodriven micropositioner mechanism with large travel range. Review of Scientific Instruments 69 4 (1998) 1785-1791
94. Moriwaki T., and Shamoto T. Ultraprecision feed system based on walking drive. Annals of the CIRP 45 1 (1996) 505-508
95. Ni J., and Zhu Z. Design of a linear piezomoter with ultra-high stiffness and nanoprecision. IEEE/ASME Transactions on Mechatronics 5 4 (2000) 441-443
96. Shamoto E., and Moriwaki T. Development of a "Walking Drive" ultraprecision positioner. Precision Engineering 20 (1997) 85-92
97. Moriyama S., Harasa T., and Takanashi A. Precision X-Y stage with a piezo-driven fine table. Journal of Japanese Society in Precision Engineering 50 (1985) 718-723
98. P. Kallio, Q. Zhou, M. Lind, H.N. Koivo, Position control of a 3 DOF piezohydraulic parallel micromanipulator, in: Proceedings of 1998 IEEE/RSJ International Conference on Intelligent Robots and Systems, vol. 2, 1998, pp. 770-775
99. Nasser K., and Leo D.J. Efficiency of frequency-rectified piezohydraulic and piezopneumatic actuation. Journal of Intelligent Material Systems and Structures 11 10 (2000) 798-810
100. Liu Y.T., and Higuchi T. Precision positioning device utilizing impact force of combined piezo-pneumatic actuator. Mechatronics 6 4 (2001) 467-473
101. Versteyhe M., Reynaerts D., and Van Brussel H. Hybrid force-position control of clamping with a piezo-stepper. IEEE Control Systems Magazine 19 2 (1999) 31-39
102. Liu Y.T., Fung R.F., and Huang T.K. Dynamic responses of a precision positioning table impacted by a soft-mounted piezoelectric actuator. Precision Engineering 28 (2004) 252-260
103. Holterman J., and de Vries T.J.A. Active damping within an advanced microlithography system using piezoelectric smart discs. Mechatronics 14 (2004) 15-34
104. Holterman J., and de Vries T.J.A. Prediction of the applicability of active damping elements in high-precision machines. Proceedings of SPIE-The International Society for Optical Engineering 5383 (2004) 211-220
105. Unno K., Kitamoto Y., Shibata T., and Makino E. Smart nano-machining and measurement system with semiconductive diamond probe. Smart Materials and Structures 10 (2001) 730-735
106. D.A. Hartman, I.E. Brazil, J.E. Talkington, D.R. Salazar, G.E. Neal, R.C. Valdez, G.J. Arellano, W.S. Duncan, M.J. Cola, V.R. Dave, In-process surface roughness prediction during turning: preliminary findings using a new sensing technique, in: Proceedings of Small Lots Intelligent Manufacturing Workshop, Santa Fe, NM, 2003.
107. D.A. Hartman, V.R. Dave, M.J. Cola, M.T. Bement, N.R. Tolk, D.C. Gubernatis, I.P. Hartman, D.R. Salazar, I.E. Brazil, In-process quality assurance during near-dry machining of plutonium, Los Alamos National Laboratory Report, 2007, in press.
108. D.A. Hartman, V.R. Dave, M.J. Cola, Real-time manufacturing performance assessment, in: Proceedings of NNSA future Technologies Conference, Washington, DC, 2004.
109. D.A. Hartman, M.T. Bement, M.J. Cola, V.R. Dave, W.H. King, In-process monitoring: a strategy for small lot production, in: Proceedings of Small Lots Intelligent Manufacturing Workshop, Santa Fe, NM, 2005.
110. Butler J.L., Butler S.C., and Clark A.E. Unidirectional magnetostrictive piezoelectric hybrid transducer. Journal of the Acoustical Society of America 88 (1990) 7-11
111. Carman G.P., and Mitrovic M. Nonlinear constitutive relations for magnetostrictive materials with applications to 1-D problems. Journal of Intelligent Material Systems and Structures 6 (1995) 673-683
112. Dapino M.J., Smith R., Faidley L.E., and Flatau A.B. A coupled structural magnetic strain and stress model for magnetostrictive transducers. Journal of Intelligent Material Systems and Structures 11 (2000) 135-152
113. E. Quandt, F. Claeyssen, Magnetostrictive materials and actuators (review), in: Proceedings of Seventh International Conference on New Actuators, 2000, pp. 100-105.
114. J.R. Michler, K.S. Moon, J.W. Sutherland, A.R. Kashani, Development of a magnetostriction based cutting tool positioner, in: Transactions of the North American Manufacturing Research Institute of SME, 1993, pp. 421-427.
115. Liu D., Sutherland J.W., Moon K.S., Sturos T.J., and Kanizar W.L. Surface texture improvement in the turning process via application of magnetostrictive actuated tool holder. Journal of Dynamic Systems Measurement and Control 120 (1998) 193-199
116. Eda H., Ohmura E., Sahashi M., and Kobayashi T. Ultra-precise machine tool equipped with a giant magnetostrictive actuator. Annals of the CIRP 41 (1992) 421-424
117. Y. Yamamoto, H. Eda, J. Shimizu, Application of giant magnetostrictive materials to positioning actuator, in: Proceedings of the 1999 IEEE/ASME International Conference on Advanced Intelligent Mechatronics, 1999, pp. 215-220.
118. Eda H., Shimizu J., and Zhou L. Study on ultra-precision machining of ceramics for optical components. Proceedings of the SPIE-The International Society for Optical Engineering 3740 (1999) 420-423
119. Rojas J., Liang C., and Geng Z.J. Experimental investigation of active machine tool vibration control. Proceedings of SPIE-The International Society for Optical Engineering 2721 (1996) 373-384
120. Z. Tang, Z. Xiang, F. Lv, Modeling and control method study of magnetostrictive micropositioner and its application, in: Proceedings of 2004 IEEE International Conference on Systems, Man, and Cybernetics, 2004, pp. 4296-4300.
121. W. Panusittikorn, P.I. Ro, Modeling and control of a magnetostrictive tool servo system, in: Proceedings of the 2004 American Control Conference, 2004, pp. 3770-3775.
122. El-Sinawi A.H., and Kashani R. Improving surface roughness in turning using optimal control of tool's radial position. Journal of Materials Processing Technology 167 (2005) 54-61
123. Al-Zaharnah I.T. Suppressing vibrations of machining processes in both feed and radial directions using an optimal control strategy: the case of interrupted cutting. Journal of Materials Processing Technology 172 (2006) 305-310
124. Jolly M.R., Bendar J.W., and Carlson J.D. Properties and applications of commercial magnetorheological fluids. Journal of Intelligent Material Systems and Structures 10 1 (1999) 5-13
125. Wang J., and Meng G. Magnetorheological fluid devices: principles, characteristics and applications in mechanical engineering. Proceedings of the Institution of Mechanical Engineers, Part L (Journal of Materials: Design and Applications) 215 3 (2001) 165-174
126. Gamota D.R., and Filisko F.E. Dynamic mechanical studied of electrorheological materials: moderate frequencies. Journal of Rheology 35 (1991) 399-425
127. Stanway R., Sproston J.L., and EI-Wahed A.K. Applications of electro-rheological fluids in vibration control: a survey. Smart Materials and Structures 5 (1996) 463-482
128. Goncalves F.D., Koo J.H., and Ahmadian M. A review of the state of the art in magnetorheological fluid technologies-part I: MR fluid and MR fluid models. The Shock and Vibration Digest 38 (2006) 203-219
129. Ashour O., Rogers C.A., and Kordonsky W. Magnetorheological fluids: materials, characterizations, and devices. Journal of Intelligent Material Systems and Structures 7 (1996) 123-130
130. Lei Y.Z. Use of the electrorheological technique (ERT) for chatter control. Proceedings of SPIE-The International Society for Optical Engineering 2620 (1995) 762-766
131. Segalman D., and Redmond J. Chatter suppression through variable impedance and smart fluids. Proceedings of the SPIE-The International Society for Optical Engineering 2721 (1996) 353-363
132. Wang M., and Fei R.Y. Improvement of machining stability using a tunable-stiffness boring bar containing an electrorheological fluid. Smart Materials and Structures 8 (1999) 511-514
133. Wang M., and Fei R.Y. Chatter suppression based on nonlinear vibration characteristic of electrorheological fluids. International Journal of Machine Tools & Manufacture 39 (1999) 1925-1934
134. Wang M., and Fei R.Y. On-line chatter detection and control in boring based on an electrorheological fluid. Mechatronics 11 7 (2001) 779-792
135. Kordonski W., and Golini D. Fundamentals of magnetorheological fluid utilization in high precision finishing. Journal of Intelligent Material Systems and Structures 10 (1999) 683-689
136. Kordonski W., and Golini D. Multiple application of magnetorheological effect in high precision finishing. Journal of Intelligent Material Systems and Structures 13 (2002) 401-404
137. Golini D., Schneider G., Flug P., and DeMarco M. Magnetorheological finishing. Optics & Photonics News 12 10 (2001) 20-24
138. Shorey A.B., Kwong K.M., Johnson K.M., and Jacobs S.D. Experiments and observations regarding the mechanisms of glass removal in magnetorheological finishing. Applied Optics 40 1 (2001) 20-33
139. Shorey A., Kordonski W., and Tricard M. Magnetorheological finishing of large and lightweight optics. Proceedings of SPIE-The International Society for Optical Engineering 5533 (2004) 99-107
140. Kim W.B., Lee S.H., and Min B.K. Surface finishing and evaluation of three-dimensional silicon microchannel using magnetorheological fluid. Journal of Manufacturing Science and Engineering 126 (2004) 772-778
141. Cheng H.B., Feng Z.J., and Wang Y.W. Optimizing parameters for magnetorheological finishing supersmooth surface. Proceedings of SPIE-The International Society for Optical Engineering 5638 (2005) 758-765
142. Schinhaerl M., Pitschke E., Geiss A., Rascher R., Sperber P., Stamp R., Smith L., and Smith G. Comparison of different magnetorheological polishing fluids. Proceedings of SPIE-The International Society for Optical Engineering 5965 (2005)
143. Akagami Y., Asari K., Jeyadevan B., and Fujita T. Characterization of particle motion for polishing and texturing under AC field by using particle dispersion type ER fluid. Journal of Intelligent Material Systems and Structures 9 (1999) 672-675
144. Kuriyagawa T., and Saeki M. Development of electrorheological fluid-assisted machining for small three-dimensional parts. Journal of Japanese Society in Precision Engineering 65 (1999) 145-149
145. Kuriyagawa T., Saeki M., and Syoji K. Electrorheological fluid-assisted ultra-precision polishing for small three-dimensional parts. Precision Engineering 26 (2002) 370-380
146. Kim W.B., Lee S.J., Kim Y.J., and Lee E.S. The electromechanical principle of electrorheological fluid-assisted polishing. International Journal of Machine Tools & Manufacture 43 (2003) 81-88
147. Zhang L., Kuriyagawa T., Kaku T., and Zhao J. Investigation into electrorheological fluid-assisted polishing. International Journal of Machine Tools & Manufacture 45 (2005) 1461-1467