Wearable Power Sources and Self-powered Sensors Based on the Triboelectric Nanogenerators

Feng, Ziang

16 November 2020

The triboelectric nanogenerator (TENG) has attracted global attention in the fields of power sources and self-powered sensors. By coupling the omnipresent triboelectrification effect and the electrical induction effect, the TENGs can transduce ambient mechanical energy into electrical energy. Such energy could be consumed instantaneously or stored for later use. In this way, they could be deployed distributedly to be compatible power sources in the era of the internet of things (IoTs), completing the powering structure that is currently relying on power plants. Also, the electrical signals can reflect the environment changes around the TENGs. Thus, the TENGs can serve as self-powered sensors in the IoTs. In this work, we adopted two approaches for TENG fabrication: the thermal drawing method (TDP) and 3D printing. With TDP, we have fabricated scalable fiber-based triboelectric nanogenerators (FTENG), which have been woven into textiles by an industrial loom for wearable use. This fabrication process can supply FTENG on a large scale and fast speed, bridging the gap between the TENG and weaving industry. With 3D printing, we have fabricated TENGs that are compatible with the shape of arbitrary substrates. They have been used as biocompatible sensors: human-skin-compatible TENG has been used to recognize silent speech in real-time by sensing the chin movement; the porcine-kidney-shaped fiber mesh has been used to monitor the perfusion rate of the organ. These works have extended the territory of TENGs and can be critical components in the IoTs. / Ph.D. / Portable electronic devices have become important components in our daily lives, and we are entering the era of the Internet of Things (IoTs), where everyday objects can be interconnected by the internet. While electricity is essential to all of these devices, the traditional power sources are commonly heavy and bulky and need to be recharged or directly connected to the immobile power plants. Researchers have been working to address this mismatch between the device and power systems. The triboelectric nanogenerators (TENG) are good candidates because they can harvest energy in the ambient environment. The users can use them to generate electricity by merely making the rubbing motion. In this work, we report two fabrication methods of the fiber-based triboelectric nanogenerators (FTENG). With the thermal drawing process, we have fabricated sub-kilometer-long FTENG and wove it with the regular cotton yarn into textiles. The wearable power source is human friendly as it does not induce any extra weight load for the user. Besides, we have demonstrated that such long fibers can work as self-powered distributed sensors, such as a Morse code generator. With 3D printing, we have fabricated FTENG-based devices that conform to the working substrates, which can be any shape. We have employed them as biofriendly sensors to translate the chin movement during speaking to language and to monitor the perfusion rate of a pig kidney. The FTENGs have offered excellent comfortability to the users and can play a vital role in reframing the power structure to be compatible with IoTs.

triboelectric nanogenerator (TENG)

thermal drawing process

3D printing

power source

self-powered sensor

Amélioration des propriétés tribologiques d'aciers inoxydables par un lubrifiant "vert" nommé AFULudine en vue de leur mise en forme. / Study of surface functionalisation of a ferritic stainless steel 441 in order to improve tribological properties

Borgeot, Melanie

28 September 2017

Dans une opération de mise en forme, les propriétés volumiques des matériaux ne sont pas les seules garantes de la réussite du procédé. Les aspects surfaciques, en lien notamment avec les propriétés tribologiques des corps en contact (tôle, lubrifiant, outils) se révèlent tout aussi importants. Il convient en ce sens de maîtriser et optimiser autant que faire se peut les conditions de contact lors d’un glissement entre la tôle et l’outillage afin d’assurer la réussite de l’opération de formage.Ces travaux de thèse portent sur la caractérisation d’une solution alternative de lubrification, nommée AFULudine, par fonctionnalisation de surface à base de molécules organiques ; solution ayant pour ambition de se substituer aux huiles minérales chlorées, performantes dans le travail des aciers inoxydables mais particulièrement nocives pour l’environnement et difficiles d’application.Les caractérisations physico-chimiques de surface (IR, électrochimie, MEB) montrent le greffage effectif d’une couche de molécules chimisorbées en surface de l’oxyde métallique, avec une cinétique de l’ordre de quelques secondes. Celle-ci est recouverte d’amas cristallisés et formés en un second temps pendant la phase d’évaporation du solvant. Des analyses morphologiques des cristaux sont réalisées montrant que leur densité et leur structure sont intimement liées au bon comportement tribologique de la surface fonctionnalisée.Le comportement tribologique des tôles (substrat en acier inoxydable ferritique K41 – 1.4509) ainsi traitées a été investigué à la fois grâce à un tribomètre d’étirage-plan permettant de découpler les influences de différentes conditions de sollicitations, telles que la pression de contact, la montée en température des outils ou encore l’influence de la déformation plastique à coeur du matériau, mais aussi en conditions réelles, à l’aide d’une presse d’emboutissage semi-industrielle. De manière plus fondamentale, la formation et la stabilité du tribofilm créé à l’interface a été analysé par l’utilisation d’un micro-tribomètre linéaire en géométrie sphère/plan couplé à de la microscopie électronique et des analyses EDS. / During forming processes, bulk properties of material are not the only guarantee in a process achievement. Surfacicalaspects, mainly coupled with tribological properties of bodies in contact (metal sheet, lubricant, tool) prove to be alsosignificant. It is therefore necessary to control and optimize the contact conditions during a sheet/tool sliding in order toguarantee the success of a forming process.The present work concerns a green lubricant solution characterization, named AFULudine, produced by thefunctionalization of the metallic surface with organic molecules. This solution was developed in substitution to the usualmineral oils, effective in stainless steel stamping but deterious for environment.Physicochemical surface characterization (IR, electrochemistry, SEM) show that the grafting of chemisorbed molecules ontothe surface occures in few seconds. This layer is covered by physisorbed and crystallised species which appear during thesolvent evaporation time. Morphological analyses of these crystals show that both density and structure determine thetribological behavior of the functionalized surface.Sheets tribological behavior (stainless steel ferritic grade, 1.4509 - K41) after treatment, has been investigated thanks to astrip drawing tribometer, allowing to dissociate the influence of various sollicitations conditions (such as contact pressure,tools temperature or plastic deformation of the material) and on an industrial scale with an Erichsen press. Fundamentally,tribo-layerʹs formation and stability have been analysed with the use of a linear micro-tribometer (ball on plane type)coupled with electronic microscopy and EDS analyses.

Comportement tribologique

Fonctionnalisation de surface

Emboutissage

Molécules organiques

Étirage-plan

Greffage

Tribological behavior

Surface functionalisation

Deep-drawing process

Stainless steel

Organic molecules

Grafting

670

DESIGN AND THERMOMECHANICAL ANALYSIS OF PRISMATIC BATTERY CELL ASSEMBLY

Thanh Nguyen (8803043)

21 June 2022

<p>A battery assembly experiences both mechanical and thermal loadings during its operation. It is critical to perform the thermomechanical analysis to propose a novel design for the highest efficiency.In this study,two main goals include mechanical characterization and deformation responses for a battery cell and assembly, as well as air-cooled concepts design and analysis.Initially, the cell dimensions were measured by cell-sectioning method, and then the mechanical properties were empirically measured by both 3-point flexural, and nanoindentation experiments. Moreover, three pairs of experiments and simulations were conducted to study mechanical behaviors on both a single cell and a battery assembly. They include (1) point-force loading for single, open cell; (2) internal pressurization for single, sealed cell; and (3) internal pressurization for battery assembly.Additionally, both parametric and experimental studies were executed to design, analyze,and validate air-cooled concepts based on the idea of microchannel heatsink. The proposed concepts have the features, which are integrated into the battery cell for generating the cooling channels. A series of thermomechanical simulations and a forced convection testbed were built for computationally and empirically analyzing the performances of the concepts. The results from the mechanical characterization showed a significant difference between the actual and nominal values of both cell dimensions and mechanical properties. Therefore, the effect of the manufacturing process to such values must be considered before inputting for analyzing the deformation responses. From the thermomechanical analyses, it was found that the mechanical loading might negatively influence the thermal performance if there were not enough mechanical supports from the air-cooling structure. The impact was minimal in the tapered-channel battery assembly. This configuration also significantly reduced the temperature difference on the cell compared with other concepts and the reference design.<br></p>

Prismatic Battery Cell

Thermomechanical Analysis

Linearly Elastic Analysis

Conjugate Heat Transfer

Deep Drawing Process

Microchannel Heat Sink

Mechanical Engineering

The Material Image

Lewis, Sage M.

15 October 2014

No description available.

Fine Arts

Art History

drawing process

materiality

photographic

experimental photo process

image

picture-object

constructed painting

sculptural drawing

paper as a medium

reproduction

photocopy printmaking

Vija Celmins

perspective

Evaluating the Factors Influencing the Friction Behavior of Paperboard during the Deep Drawing Process

Lenske, Alexander, Müller, Tobias, Penter, Lars, Schneider, Matti, Hauptmann, Marek, Majschak, Jens-Peter

28 June 2018

Deep drawing of paperboard with rigid tools and immediate compression has only a small presence in the market for secondary packaging solutions due to a lack of understanding of the physical relations that occur during the forming process. As with other processes that deal with interactions between two solids in contact, the control of the factors that affect friction is important due to friction’s impact on runnability and process reliability. A new friction measurement device was developed to evaluate the factors influencing the friction behavior of paperboard such as under the specific conditions of the deep drawing process, which differ from the standard friction testing methods. The tribocharging of the contacting surfaces, generated during sliding friction, was determined to be a major influence on the dynamic coefficient of friction between paperboard and metal. The same effect could be examined during the deep drawing process. With increased contact temperature due to the heating of the tools, the coefficient of friction decreased significantly, but it remained constant after reaching a certain charging state after several repetitions. Consequently, to avoid ruptures of the wall during the forming process, tools that are in contact with the paperboard should be heated.

Reibverhalten

Reibungsmessung

Karton

Tribokontrolle

Kontaktelektrifizierung

Triboelektrifizierung

Tiefziehprozess

3D-Umformung

TU Dresden

Publikationsfond

Friction behavior

Friction measurement

Paperboard

Tribocharging

Contact electrification

Triboelectrification

Deep drawing process

3D-forming

TU Dresden

Publishing Fund

ddc:500

rvk:TA 1000

Evaluating the Factors Influencing the Friction Behavior of Paperboard during the Deep Drawing Process

Lenske, Alexander, Müller, Tobias, Penter, Lars, Schneider, Matti, Hauptmann, Marek, Majschak, Jens-Peter

28 June 2018

Deep drawing of paperboard with rigid tools and immediate compression has only a small presence in the market for secondary packaging solutions due to a lack of understanding of the physical relations that occur during the forming process. As with other processes that deal with interactions between two solids in contact, the control of the factors that affect friction is important due to friction’s impact on runnability and process reliability. A new friction measurement device was developed to evaluate the factors influencing the friction behavior of paperboard such as under the specific conditions of the deep drawing process, which differ from the standard friction testing methods. The tribocharging of the contacting surfaces, generated during sliding friction, was determined to be a major influence on the dynamic coefficient of friction between paperboard and metal. The same effect could be examined during the deep drawing process. With increased contact temperature due to the heating of the tools, the coefficient of friction decreased significantly, but it remained constant after reaching a certain charging state after several repetitions. Consequently, to avoid ruptures of the wall during the forming process, tools that are in contact with the paperboard should be heated.

info:eu-repo/classification/ddc/500

ddc:500

New Method to Evaluate the Frictional Behavior within the Forming Gap during the Deep Drawing Process of Paperboard

Lenske, Alexander, Müller, Tobias, Hauptmann, Marek, Majschak, Jens-Peter

22 May 2019

To evaluate the influence of different normal forces and contact temperatures on the frictional behavior of paperboard during the deep drawing process, a new measurement punch was developed to measure the normal force, which induced the friction within the gap between the forming cavity and punch. The resulting dynamic coefficient of friction was calculated and reproduced via a new developed substitute test for the friction measurement device, which was first introduced in Lenske et al. (2017). The normal force within the forming gap during the deep drawing process was influenced by the blankholder force profile, the contact temperature, and the fiber direction. The friction measurements with the substitute test showed a strong dependency between the applied normal force and the dynamic coefficient of friction. Furthermore the frictional behavior was influenced by the contact temperature and the wrinkle formation.

info:eu-repo/classification/ddc/500

ddc:500