Embedded smart sensing devices incorporating …euronanoforum2015.eu/wp-content/uploads/2015/06/9_SmartStructureIn... · Embedded smart sensing devices incorporating piezoelectric

HORIZON 2020 EUROPEAN UNION FUNDING FOR RESEARCH & INNOVATION

Embedded smart sensing devices incorporating piezoelectric energy harvesters. VERMON SA, France An NGUYEN-DINH, Vice-President, Director of Technology

Contents

•  VERMON SA, France •  wireless SHM (Structure Health Monitoring) •  Piezoelectricity & Energy Harvesting •  Applications •  Perspectives / conclusions

An NGUYEN-DINH, VERMON SA Vice-President

Dir. of Tech

[email protected]

VERMON is anchored in both medical and industrial ultrasound markets

-  SME created in 1984 -  160 pers (30 in R&D) -  Turnover: 26,5M€ (2014) -  >10% CAGR -  >20% of turnover dedicated to R&D -  87% to export

Facilities -  Located in Tours, France -  > 4000sqm -  ISO9001, ISO13485 and ISO14001 QMS.

OEM provider of ultrasound turnkey solutions

Main core technologies -  Bulk piezoelectric technologies -  Electrostatic MEMS-based technologies

Applications -  Imaging / Monitoring -  Therapy -  NDT/SHM -  Energy harvesting

180 rue du Général Renault 37038 TOURS CEDEX 1, France

www.vermon.com

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Energy harvesting system block diagram

VERMON, France

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Applications addressable by energy harvesters

VERMON, France

Piezoelectric energy harvesting

PIEZOELECTRICITY is unique in that allows the generation of electricity from what are considered as waste mechanical forces. Piezoelectric effect is defined as the electrical polarization of materials due to application of mechanical stress or strain.

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VERMON, France

Off-Resonance Resonance

Mechanical sources Compression load Vibrations

Frequency N/A Tunable

Structure Stack / cymbal / drum.. Cantilever / bridge..

Intrinsic features High energy output Withstand high mechanical load Mechanical amplifier compatible (cymbal) Dynamic excitation stress Robust manufacturing process

Tunable resonant frequency Simple structures Compact sizes / miniaturisable Cost efficient (development & fab) Reliable performance

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Modes of operations

VERMON, France

Cantilever energy harvester

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bimorph cantilever in d31 piezoelectric mode

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Piezo cantilever energy harvester (component)

Piezo harvester + rectifier + rechargeable battery or super caps (scalable energy harvesting sub-system)

Piezo harvester + rectifier + sensors + signal proc. + communication (embeddable autonomous sensor node)

Embeddable autonomous sensor node (ASN)

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Some previous generations of sensor nodes

Next Gen: consumption<few µW / integrated energy harvesting / wireless transponder / adaptable lifespan / conformable / smart power management / etc..

VERMON, France

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ASN network

(a) Typical wireless sensor network scenario. (b) Sensor node block diagram.

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Surface  roughness  (PZT)     Op5cal  Thickness  control   Poling  and  electrode  pla5ng  X50  

⇒  Thinned bulk PZT layers ⇒  Metallic/Organic shim materials ⇒  Assembly method (reliability & robustness)

Manufacturing process (cantilever)

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Performance assessment

100 105 110 115 120 125 1300

5

10

15

20

25

30

35

RMS

pow

er d

istr

ibut

ion(µW

) @

200K

Ω

Time Frequency (Hz)

0.14G0.19G0.23G0.28G0.32G0.38G

•  Performances : -  25µW/cm2 @ 0,24G 24,5Hz -  3Vrms -  Q=24 -  non-linear electromechanical

behavior

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Structure health monitoring (SHM)

Requirements for SHM energy harvester §  High reliability

§  Embeddable within the structure §  Long lifespan

§  Harsh environment compatible (T°, pressure, radiation, chemical) §  Efficiency §  High power density

§  Cost efficient

Aircraft applications Maintenance costs for airlines companies: 10b$

35% of them can be saved with embedded autonomous sensors.

Various types of sensors: acoustic, LRU, inertial.. Vibration frequencies: 50-150Hz.

Typical acceleration: 0,2 to 1G Constraints: flat design, robust, reliable, long

lifespan.

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General specifications: Vibration conditions

–  Harvesting frequency range from 10 to 50Hz –  1G max acceleration

Geometry –  Flat shape to be incorporated into a composite

sandwich layer thickness –  Compatible with internal stress/strain

Detection capabilities and localization –  Passive acoustic or LRU sensors for guided wave

processing –  Other sensors

Autonomous  acous+c  sensor  nodes  

ASN for SHM

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•  Heart as vibrational source –  Direct conversion (external patches) –  Hear motion (external or internal

capsules •  Power output

–  >10µW/cm2 continuous power output –  Up to 2.5V voltage

•  Quality standards & requirements –  20-25 years lifespan –  Comply with ISO60601 standards on

active implantable medical devices •  Biocompatibility •  Electrical safety

“Conformal piezoelectric energy harvesting from motions of the heart, lung, and diaphragm” C. Dagdeviren

“Implantable vibrational low frequency energy harvester”, VERMON

Piezoelectric energy harvesters for medical

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modelling

Micromachining

Electronics

Integration

WSN

Sensing

Test & validation

Piezoelectric energy harvesting, a multi-disciplinary domain.

academic-industry synergy

Piezoelectric design

micro-machining

smart-integration

low power Electronics

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MEMS-based    

Macro-Fab  

Thin films   Thin films   Thick films   Thinned bulk  Chemical vapor

deposition   Sputtering   Sol-gel  

Performances  LF Energy harvesting cap.   kHz range   kHz range   <100Hz   5-50Hz  

Power density   mid   mid   mid   high  Aging   na   na   na   qualif. in prog  

Manufacturing capabilities  bimorph   difficult   difficult   average   easy  

WLP / PLP   yes   yes   yes   yes  piezo thickness   <1µm   <3µm   <10µm   10µm-50µm  

Technology development  Design adjustment level   low   low   high   high  

Feasibility development cost   >200k€   >200k€   <100k€   <50k€

Product industrialization   >1M€   >1,5M€   >250k€   <250k€

Product cost / equipment cost  Cost/Unit   <5€   <5€   ?   >20€

Quantity/wafer   160/ 6“wafer   160/ 6“wafer   na   na  

Development  cycle   >2years   >2years   >1  year   6 months

Piezoelectric energy harvesters technology comparison

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Conclusions

Validated Competitive Performances (10-25µW/cm2) Low technology access investment High degree of flexibility

•  Large choice of materials and dimensions •  Application compatibility

An efficient way to fast prototyping and demonstrator validation

•  Extended resonance frequency range (10Hz to 4KHz) •  Low to medium volume compatible

Aging : > 10years lifespan Versatile (medical or industrial)

Perspectives High expectation market potential Stable & well-known principles Proven durability Room for new designs and optimizations High degree of customization

Still in development Non-linear behavior (medium term) Robustness in harsh environment (short term) Reliability (medium term)

On-going Research Programs (2015-2018) Smart-Memphis, H2020-GA644378 (2015-2016) Laureat-ANR-French National Agency for Research; ANR-14-CE17-0010

Contact: An Nguyen-Dinh [email protected] Phone: +33 247374278

VERMON, France