Electrostatic kinetic energy harvesting:
Saved in:
| Main Authors: | , , |
|---|---|
| Format: | Book |
| Language: | English |
| Published: |
London
ISTE
2016
|
| Series: | Nanotechnologies for energy recovery set
volume 3 |
| Subjects: | |
| Links: | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=028991413&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=028991413&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA |
| Physical Description: | xiii, 226 Seiten Diagramme |
| ISBN: | 9781848217164 |
Staff View
MARC
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Record in the Search Index
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| adam_text | Contents
p
Preface .................................................................. ix
Introduction: Background and Area of Application........................ xi
Chapter 1. Introduction to Electrostatic
Kinetic Energy Harvesting .............................................. 1
Chapter 2. Capacitive Transducers....................................... 7
2.1. Presentation of capacitive transducers ........................ 7
2.2. Electrical operation of a variable capacitor............ 11
2.3. Energy and force in capacitive transducers..................... 12
2.3.1. Energy of a capacitor........................................ 12
2.3.2. Force of the capacitor....................................... 14
2.3.3. Capacitive transducers biased by an electret layer......... 17
2.4. Energy conversion with a capacitive transducer................. 20
2.5. Optimization of the operation of a capacitive transducer....... 21
2.6. Electromechanical coupling ...................................... 23
2.7. Conclusions...................................................... 24
2.8. Appendix: proof of formula [2.32] for the energy converted
in a cycle............................................................ 24
Chapter 3. Mechanical Aspects of Kinetic Energy Harvesters:
Linear Resonators........................................................ 27
3.1. Overview of mechanical forces and the resonator model.......... 27
3.1.1. Linear resonator as the main model of the mechanical part.. 27
3.1.2. The nature and effect of the transducer force.............. 30
3.1.3. Remarks on mechanical forces................................. 33
3.2. Interaction of the harvester with the environment................ 36
vi Electrostatic Kinetic Energy Harvesting
3.2. L Power balance of KEHs.......................................... 36
3.2.2. Efficiency of KEHs............................................. 40
3.3. Natural dynamics of the linear resonator........................... 42
3.3.1. Behavior of the resonator with no input........................ 42
3.3.2. Energy relation for the resonator with no input................ 44
3.3.3. Forced oscillator and linear resonance......................... 45
3.3.4. Periodic external vibrations................................... 49
3.3.5. Energy relation for a forced resonator . . .................... 50
3.4. The mechanical impedance............................................. 52
3.5. Concluding remarks................................................... 54
Chapter 4. Mechanical Aspects of Kinetic Energy Harvesters:
Nonlinear Resonators ......................................................... 55
4.1. Nonlinear resonators with mechanically induced nonlinearities .... 55
4.1.1. Equation of the nonlinear resonator............................ 55
4.1.2. Free oscillations of nonlinear resonator: qualitative description
using potential wells................................................... 60
4.1.3. Free oscillations of nonlinear resonator:
semi-analytical approach................................................ 62
4.1.4. Forced nonlinear resonator and nonlinear resonance............. 63
4.2. Review of other nonlinearities affecting the dynamics of the resonator:
impact, velocity and frequency amplification and electrical softening .... 68
4.3. Concluding remarks: effectiveness of linear and nonlinear resonators . 71
Chapter 5. Fundamental Effects of Nonlinearity ............................. 75
5.1. Fundamental nonlinear effects: anisochronous and
anharmonic oscillations................................................... 75
5.2. Semi-analytical techniques for nonlinear resonators.................. 79
5.2.1. Normalized form of nonlinear resonators........................ 79
5.2.2. Anharmonic oscillations demonstrated by straightforward
expansion............................................................... 81
5.2.3. Anisochronous oscillations demonstrated by the LPM............... 84
5.2.4. Multiple scales method........................................... 88
5.2.5. Nonlinearity of a general form................................... 91
5.3. Concluding remarks................................................... 95
Chapter 6. Nonlinear Resonance and its Application to
Electrostatic Kinetic Energy Harvesters ...................................... 97
6.1. Forced nonlinear resonator and nonlinear resonance................... 97
6.1.1. Analysis of forced oscillations using the multiple
scales method......................................................... 97
6.1.2. Forced oscillations with a general form of nonlinear force..... 102
Contents vii
6.2. Electromechanical analysis of an electrostatic kinetic energy
harvester ................................................................ 105
6.2.1. Statement of the problem ...................................... 105
6.2.2. Mathematical model of the constant charge circuit.............. 106
6.2.3. Steady-state nonlinear oscillations.............................. 109
6.2.4. Dynamical effects and bifurcation behavior .................... 113
6.2.5. Other conditioning circuits...................................... 115
6.3. Concluding remarks.................................................. 119
Chapter 7. MEMS Device Engineering for e-KEH................................ 121
7.1. Silicon-based MEMS fabrication technologies......................... 121
7.1.1. Examples of bulk processes ...................................... 122
7.1.2. Thin-film technology with sacrificial layer...................... 123
7.2. Typical designs for the electrostatic transducer.................. 124
7.2.1. Capacitive transducers with gap-closing electrode variation .... 125
7.2.2. Strategies on the stopper s location in gap-closing e-KEH...... 128
7.2.3. Capacitive transducers with overlapping electrode motion....... 130
7.3. e-KEHs with an electret layer .................................... 133
Chapter 8. Basic Conditioning Circuits for Capacitive Kinetic
Energy Harvesters ................................................... 135
8.1. Introduction ....................................................... 135
8.2. Overview of conditioning circuit for capacitive kinetic
energy harvesting....................................................... 136
8.3. Continuous conditioning circuit: generalities....................... 138
8.3.1. Qualitative discussion on operation of the circuit ........ 139
8.3.2. Analytical model in the electrical domain...................... 140
8.4. Practical study of continuous conditioning circuits............... 141
8.4.1. Gap-closing transducer........................................... 141
8.4.2. Area overlap transducer......................................... 145
8.4.3. Simple conditioning circuit with diode rectifiers.............. 148
8.5. Shortcomings of the elementary conditioning circuits: auto-increasing
of the biasing............................................................ 149
8.5.1. Appendix: listing of the Eldo netlist used to obtain the presented
plots................................................................... 152
Chapter 9. Circuits Implementing Triangular QV Cycles ...................... 155
9.1. Energy transfer in capacitive circuits ............................ 155
9.1.1. Energy exchange between two fixed capacitors .................. 155
9.1.2. Case of a voltage source charging a capacitor.................. 156
9.1.3. Inductive DC-DC converters....................................... 157
9.1.4. Use of a variable capacitor...................................... 161
viii Electrostatic Kinetic Energy Harvesting
9.2. Conditioning circuits implementing triangular QV cycles........ 163
9.2.1. Constant-voltage conditioning circuit....................... 163
9.2.2. Constant-charge conditioning circuits....................... 165
9.2.3. Analysis of the circuit implementing a constant-charge
QV cycle........................................................... 166
9.2.4. Practical implementation.................................... 169
9.3. Circuits implementing triangular QV cycles: conclusion......... 171
Chapter 10. Circuits Implementing Rectangular
QV Cycles, Part I ....................................................... 173
10.1. Study of the rectangular QV cycle............................. 173
10.2. Practical implementation of the charge pump................... 178
10.2.1. Evolution of the harvested energy.......................... 180
10.3. Shortcomings of the single charge pump and required
improvements.......................................................... 182
10.3.1. Need for a flyback........................................... 182
10.3.2. Auto-increasing of the internal energy ...................... 183
10.4. Architectures of the charge pump with flyback................. 184
10.4.1. Resistive flyback............................................ 184
10.4.2. Inductive flyback ......................................... 185
10.5. Conditioning circuits based on the Bennet’s doubler........... 188
10.5.1. Introduction of the principle ............................. . 188
10.5.2. Analysis of the Rennet’s doubler conditioning circuit...... 191
10.5.3. Simulation of a Rennet’s doubler............................. 199
Chapter 11. Circuits Implementing Rectangular
QV Cycles, Part II ........................................................ 203
11.1. Analysis of the half-wave rectifier with a transducer biased by an
electret............................................................ 203
11.2. Analysis of the full-wave diode rectifier with transducer biased by an
electret ............................................................. 205
11.3. Dynamic behavior and electromechanical coupling of rectangular
QV cycle conditioning circuits ....................................... 210
11.4. Practical use of conditioning circuits with rectangular QV cycle ... 215
11.5. Conclusion on conditioning circuits for e-KEHs.................. 216
Bibliography .............................................................. 217
Index
225
NANOTECHNOLOGIES FOR ENERGY RECOVERY SET
Coordinated by Pascal Maigne
As we enter the age of the Internet of Things (loT), miniaturization and
efficiency are going to be predominant trends in microelectronics. Since
the technologies of the future inevitably need energy sources, energy
harvesting will continue to develop into an extremely active, versatile and
growing area that attracts engineers and scientists from the field of
electronics, microsystems and materials science. This book discusses
electrostatic kinetic energy harvesting, which, in the opinion of the
authors, is under-represented in the literature despite its particular
compatibility to microtechnological applications.
While the primary focus of this book is energy harvesting employing the
electrostatic transduction, it does cover all aspects necessary to
understand and design an efficient harvester, including linear and
nonlinear resonators, electrostatic transaction principles, microfabrication
processes and the design of conditioning electronics.
Chapters 1, 2 and 7 discuss a capacitive energy harvester as a system,
with additional chapters devoted to the operation in both the electrical
and the mechanical domains. Chapters 3 through 6 discuss mechanical
aspects of harvesters, and Chapters 8 through 11 are devoted to
electronic conditioning circuitry. The authors have made a choice to
present the material at a relatively high level of abstraction, limiting the
discussion to the aspects that have most impact on the global operation
of the harvester, while still providing the reader with a thorough
understanding of the role and function of each component in an energy
harvester.
Philippe Basset is Associate Professor at University Paris-Est, France. He
is an expert in the fields of microelectromechanical systems (MEMS),
electrical engineering, electronic engineering and engineering physics.
Elena Blokhina is a lecturer at University College Dublin, Ireland. Her
expertise lies in the area of nonlinear circuits and systems, oscillation
theory and mathematical modeling.
Dimitri Galayko is Associate Professor at the UPMC-Sorbonne
Universities in Paris, France. He is an expert in the field of
microelectronics and in the field of integrated system design and
modeling.
|
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| id | DE-604.BV043576685 |
| illustrated | Not Illustrated |
| indexdate | 2024-12-20T17:39:55Z |
| institution | BVB |
| isbn | 9781848217164 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-028991413 |
| oclc_num | 967241260 |
| open_access_boolean | |
| owner | DE-703 |
| owner_facet | DE-703 |
| physical | xiii, 226 Seiten Diagramme |
| publishDate | 2016 |
| publishDateSearch | 2016 |
| publishDateSort | 2016 |
| publisher | ISTE |
| record_format | marc |
| series | Nanotechnologies for energy recovery set |
| series2 | Nanotechnologies for energy recovery set Nanoscience and nanotechnology series |
| spellingShingle | Basset, Philippe Blokhina, Elena Galayko, Dimitri Electrostatic kinetic energy harvesting Nanotechnologies for energy recovery set Energy harvesting Microharvesters (Electronics) TECHNOLOGY & ENGINEERING / Mechanical bisacsh Energy harvesting fast Microharvesters (Electronics) fast Nanotechnologie (DE-588)4327470-5 gnd MEMS (DE-588)4824724-8 gnd Mikrosystemtechnik (DE-588)4221617-5 gnd Energy Harvesting (DE-588)7664612-9 gnd |
| subject_GND | (DE-588)4327470-5 (DE-588)4824724-8 (DE-588)4221617-5 (DE-588)7664612-9 |
| title | Electrostatic kinetic energy harvesting |
| title_auth | Electrostatic kinetic energy harvesting |
| title_exact_search | Electrostatic kinetic energy harvesting |
| title_full | Electrostatic kinetic energy harvesting Philippe Basset, Elena Blokhina, Dimitri Galayko |
| title_fullStr | Electrostatic kinetic energy harvesting Philippe Basset, Elena Blokhina, Dimitri Galayko |
| title_full_unstemmed | Electrostatic kinetic energy harvesting Philippe Basset, Elena Blokhina, Dimitri Galayko |
| title_short | Electrostatic kinetic energy harvesting |
| title_sort | electrostatic kinetic energy harvesting |
| topic | Energy harvesting Microharvesters (Electronics) TECHNOLOGY & ENGINEERING / Mechanical bisacsh Energy harvesting fast Microharvesters (Electronics) fast Nanotechnologie (DE-588)4327470-5 gnd MEMS (DE-588)4824724-8 gnd Mikrosystemtechnik (DE-588)4221617-5 gnd Energy Harvesting (DE-588)7664612-9 gnd |
| topic_facet | Energy harvesting Microharvesters (Electronics) TECHNOLOGY & ENGINEERING / Mechanical Nanotechnologie MEMS Mikrosystemtechnik Energy Harvesting |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=028991413&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=028991413&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA |
| volume_link | (DE-604)BV043899418 |
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