Bezventilové plunžrové čerpadlo / Valveless Plunger Pump

Machů, Tomáš

January 2021

This thesis deals with valveless reciprocating pumps. Within the thesis several designs of pump geometry are demonstrated. Their parameters were obtained using computational fluid dynamics. Reciprocating piston movement was simulated by time dependent inlet boundary condition or by dynamic mesh. The individual variants were compared mainly from point of view of volumetric efficiency, which was the main evaluated parameter. Results of calculations are presented as dependencies of volumetric efficiency on frequency and amplitude of piston motion and on value of backpressure. Two variants of the prototype pump geometry were manufactured to experimentally validate parameters obtained from calculations. Volumetric efficiency together with hydraulic efficiency were evaluated from measured data.

Řízení a vyhodnocení laserových mikromanipulačních experimentů / Controlling and Evaluation of Laser Micromanipulation Experiments

Kaňka, Jan

January 2012

This work is focused on the development of a user friendly software interface using the LabViewTM environment that simplifies running of various experiments using laser micromanipulations and laser microspectroscopy of living microorganisms. Both techniques have been developing very fast for the last decade and belong to the growing group of contact-less and nondestructive techniques for manipulation and diagnostics of individual living microorganisms, cells, or viruses. Within this project we mastered the driving of peripheries, calibration of CCD scene, real-time image processing of the CCD scene, automatic selection of the cell for further laser processing, acquisition and processing of the Raman spectrum from living microorganisms. The final goal of our activity is fully automatic laser-based sorter of living cells depending on their chemical compositions. This work has been elaborated at the Institute of Scientific Instruments of the ASCR, v.v.i. under the supervision of prof. Pavel Zemanek.

Microfluidic blood sample preparation for rapid sepsis diagnostics

Hansson, Jonas

January 2012

Sepsis, commonly referred to as blood poisoning, is a serious medical condition characterized by a whole-body inflammatory state caused by microbial infection. Rapid treatment is crucial, however, traditional culture-based diagnostics usually takes 2-5 days.  The overall aim of the thesis is to develop microfluidic based sample preparation strategies, capable of isolating bacteria from whole blood for rapid sepsis diagnostics.  Although emerging technologies, such as microfluidics and “lab-on-a-chip” (LOC) devices have the potential to spur the development of protocols and affordable instruments, most often sample preparation is performed manually with procedures that involve handling steps prone to introducing artifacts, require skilled technicians and well-equipped, expensive laboratories.  Here, we propose the development of methods for fast and efficient sample preparation that can isolate bacteria from whole blood by using microfluidic techniques with potential to be incorporated in LOC systems. We have developed two means for high throughput bacteria isolation: size based sorting and selective lysis of blood cells. To process the large blood samples needed in sepsis diagnostics, we introduce novel manufacturing techniques that enable scalable parallelization for increased throughput in miniaturized devices. The novel manufacturing technique uses a flexible transfer carrier sheet, water-dissolvable release material, poly(vinyl alcohol), and a controlled polymerization inhibitor to enable highly complex polydimethylsiloxane (PDMS) structures containing thin membranes and 3D fluidic networks. The size based sorting utilizes inertial microfluidics, a novel particles focusing method that operates at extremely high flow rates. Inertial focusing in flow through a single inlet and two outlet, scalable parallel channel devices, was demonstrated with filtration efficiency of >95% and a flowrate of 3.2 mL/min. Finally, we have developed a novel microfluidic based sample preparation strategy to continuously isolate bacteria from whole blood for downstream analysis. The method takes advantage of the fact that bacteria cells have a rigid cell wall protecting the cell, while blood cells are much more susceptible to chemical lysis. Whole blood is continuously mixed with saponin for primary lysis, followed by osmotic shock in water. We obtained complete lysis of all blood cells, while more than 80% of the bacteria were readily recovered for downstream processing. Altogether, we have provided new bacteria isolation methods, and improved the manufacturing techniques and microfluidic components that, combined offer the potential for affordable and effective sample preparation for subsequent pathogen identification, all in an automated LOC format. / QC 20120611

3D fluidic networks

bacteria isolation

inertial microfluidics

lab-on-chip

microfluidics

particle filtration

PDMS membrane

selective cell lysis. sepsis

Engineering and Technology

Teknik och teknologier

Variable Stiffness Links for Collaborative Robots

Zhou, Yitong

January 2020

No description available.

Mechanical Engineering

Robotics

Studies on construction of the capillary chromatography based on specific fluidic behavior of mixed solvent solution in microspace and consideration of the fluidic behavior / 微小空間における溶媒混合溶液の特異的流体挙動を応用したキャピラリークロマトグラフィーの構築とその流体挙動の解明に関する研究 / ビショウ クウカン ニオケル ヨウバイ コンゴウ ヨウエキ ノ トクイテキ リュウタイ キョドウ オ オウヨウ シタ キャピラリー クロマトグラフィー ノ コウチク ト ソノ リュウタイ キョドウ ノ カイメイ ニカンスル ケンキュウ

藤永 慧, Satoshi Fujinaga

22 March 2016

管径方向分配現象(Tube Radial Distribution Phenomenon: TRDP)を応用したクロマトグラフィー(TRDC)に関する研究と、TRDPの現象解明に関する研究を行った。TRDCに関する研究として、TRDCによる分離性能の改善と最適条件の検討、分析対象物の拡大を行い、併せてTRDCシステムの構築に貢献した。TRDPに関する研究として、TRDPの発生に必要な条件の検討、新たなTRDPを発生する溶液系の導入、及びTRDPの相形成の規則性について調べた。その結果、TRDPの全体的な原理の解明に貢献した。 / The author studied the development of capillary chromatography (TRDC) based on TRDP and the elucidation of TRDP. For study of TRDC, I studied the improvement of separation performance, the optical condition of TRDC and the expansion of analyte. As a result, the author contributed to the construction of TRDC system. For study of TRDP, The author studied the condition to generate TRDP, the introduction of the new solution system to generate TRDP, and the regularity of the phase formation of TRDP. As a result, the author contributed to the elucidation of the principle of TRDP. / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University

溶媒混合溶液

流体挙動

微小空間

capillary chromatography

mixed solvent solution

fluidic behavior

microspace

Application of Fluidic Oscillator Separation Control to a Square-back Vehicle Model

Metka, Matthew

January 2015

No description available.

Aerospace Engineering

Automotive Engineering

Mechanical Engineering

separation control

aerodynamics

drag reduction

bluff body

Ahmed model

fluidic oscillator

bluff body wake

active flow control

Non-isothermal characterization of squeezed thin films in the presence of biofluids and suspended ultrafine particles

Khaled, Abdul Rahim Assaad, Mr.

January 2003

No description available.

Engineering, Mechanical

thin films

squeezing

oscillations

ultrafine particles

flow

heat transfer

internal pressure pulsations

seals

leakage

fluidic cell

enhancement

flow disturbances

thermal disturbances

Effet des films liquides en évaporation / Effect of evaporating liquid films

Chauvet, Fabien

26 November 2009

Ce travail est axé sur l'étude de l'évaporation lente d'un liquide confiné dans un tube capillaire de section carrée, en lien avec l'étude du phénomène de séchage. Dans un tel capillaire, si le liquide est suffisamment mouillant, des films liquides se forment par capillarité le long des coins internes. L'évaporation du liquide en sommet de film engendre un pompage capillaire et l'espèce volatile est alors transportée, sous phase liquide, au plus près du sommet du capillaire. Ce mode de transport dépend de la compétition entre les effets capillaires et les effets visqueux et de gravité qui s'opposent tous deux au mouvement du liquide vers le sommet du capillaire. Ces films liquides sont étudiés en adoptant une approche expérimentale. Le principe des expériences est de laisser un liquide volatil s'évaporer dans un tube capillaire carré. Plusieurs expériences d'évaporation sont réalisées en faisant varier la nature du liquide, la taille du capillaire et son orientation (horizontale et verticale). Une méthode de thermographie infra-rouge permet de mesurer le profil de température le long du capillaire. Le refroidissement induit par le changement de phase liquide-vapeur ainsi que sa position sont alors mesurables. A partir d'une méthode de visualisation par ombroscopie, plusieurs grandeurs sont mesurées : position du ménisque principal, taux d'évaporation et épaisseur relative des films. En s'appuyant sur une analyse simple du transfert de masse, on montre alors que les cinétiques d'évaporation obtenues expérimentalement se divisent en trois principales phases caractéristiques, ressemblant fortement aux trois périodes de la cinétique classique de séchage des milieux poreux capillaires. L'analyse de l'hydrodynamique des films montre qu'il est indispensable de prendre en compte l'arrondi interne des coins des capillaires dans la modélisation de l'écoulement au sein des films. On montre notamment que le phénomène étudié est très sensible à ce paramètre, qui limite l'extension des films. Ce travail expérimental a permis de développer une modélisation du transfert de masse dans la configuration étudiée, couplée à une modélisation de l'écoulement des films, et finalement de proposer un modèle de séchage d'un capillaire carré quantitativement satisfaisant. / In connection with the study of the phenomenon of drying, this work focuses on the study of slow evaporation of a liquid confined in a capillary of square cross section. In such a capillary, if the liquid wetting contact angle is low enough, liquid films are trapped by capillary forces along the capillary inside corners. Evaporation of the liquid at the film top creates a capillary pumping. The volatile species is then transported in liquid phase to the top of the capillary. This efficient mode of transport depends on the competition between the effects of capillarity and the effects of viscosity and gravity both opposing to the liquid flow towards the top of the capillary. In this work, the liquid films are studied experimentally.The principle of the experiments is to leave a volatile liquid evaporate in a square capillary tube. Several evaporation experiments are conducted, varying the liquid, the capillary tube size and its orientation (horizontal and vertical). An infrared thermography method allows to measure the temperature profile along the capillary. The cooling induced by the liquid-vapor phase change and its location is then measured. Owing to an ombroscopy visualization method, the location of the bulk meniscus, the evaporation rate and the relative thickness of the films can be measured. The experimental results show that the evaporation kinetics is similar to the drying kinetics of capillary porous media. This finding allows to study evaporation in a square capillary by analogy with the study of drying of capillary porous media. Based on a simple analysis of mass transfer in the system, it is then shown that the evaporation kinetics obtained experimentally can be divided into three main characteristic phases. The analysis of the hydrodynamic of the films shows that it is essential to take into account the roundeness of the capillary tube inside corners in the modelling of the flow in the films. We show that the phenomenon studied is very sensitive to the degree of roundedness of the tube internal corners, which limits the extension of the films. Modelling of the mass transfer coupled with modelling the film flow lead to a quantitatively satisfactory model of the drying of a square capillary tube.

Capillarite

Mouillabilite

Tube capillaire

Films liquides

Séchage

Transfert de masse

Micro-fluidique

Thermographie infra-rouge

Ombroscopie

Capillarity

Wetting

Capillary tube

Liquid films

Drying

Evaporation

Liquid-vapor phase change

Mass transfer

Micro-fluidic

Infrared thermography

Ombroscopy

An Electromagnetic Actuated Microvalve Fabricated on a Single Wafer

Sutanto Bintoro, Jemmy

23 November 2004

Microvalves are essential components of the miniaturization of the fluidic systems to control of fluid flow in a variety of applications as diverse as chemical analysis systems, micro-fuel cells, and integrated fluidic channel arrangements for electronic cooling. Using microvalves, these systems offer important advantages: they can operate using small sample volumes and provide rapid response time. This PhD dissertation presents the world first electromagnetically actuated microvalve fabricated on a single wafer with CMOS compatibility. In this dissertation, the design, fabrication, and testing results of two different types of electromagnetic microvalves are presented: the on/off microvalve and the bistable microvalve with latching mechanism. The microvalves operate with power consumption of less than 1.5 W and can control the volume flow rate of DI water, or a 50% diluted methanol solution in the range 1 - 50 µL in. The leaking rate of the on/off microvalve is the order of 30 nL/min. The microvalve demonstrated a response time for latching of 10 ms in water and 0.2 ms in air. This work has resulted in a US patent, application no. 10/699,210.Other inventions that have been developed as a result of this research are bidirectional, and bistable-bidirectional microactuators with latching mechanism, that can be utilized for optical switch, RF relay, micro mirror, nano indenter, or nano printings.

MEMS

Microvalve

Electromagnetic

Bistable

Micro magnet

Actuator

Valves Design and construction

Actuators Design and construction

Fluidic devices Design and construction

Études de systèmes thermo-fluidiques auto-oscillants pour des applications de récupération d'énergie thermique

Monin, Thomas

January 2017

Les progrès technologiques considérables menés depuis ces dernières décennies nous permettent aujourd’hui de disséminer dans notre environnement une nuée de noeuds de capteurs communicants combinant la taille micrométrique et la consommation dérisoire caractéristiques des MEMS avec la puissance des protocoles de communications Internet. L’Internet des Objets, formé par ce réseau de capteurs, possède le potentiel d‘optimiser un grand panel d’applications industrielles et domotiques. Le nouveau défi, que la communauté du Energy Harvesting tente de relever depuis une décennie maintenant, est de rendre ces noeuds de capteurs autonomes en les alimentant grâce à l’énergie perdue dans leur environnement. Dans ces travaux de recherche, nous explorons le potentiel d’un principe thermo-fluidique auto-oscillant pour la génération d’énergie utile à partir d’une source thermique de faible qualité. L’implémentation de cette technologie en tant que machine thermique est étudiée et mène à la caractérisation d’un nouveau cycle thermodynamique caractéristique du SOFHE (Self Oscillating Fluidic Heat Engine). Nous montrons, par une approche phénoménologique, que notre machine thermique se comporte comme un oscillateur mécanique, excité par les évaporations et condensations successives du fluide de travail. Ces changements de phase alternatifs mettent en mouvement une colonne d’eau, jouant le rôle de masse, couplée à une zone de vapeur, jouant le rôle d’un ressort. Une étude de l’influence du couplage du SOFHE avec un transducteur électromécanique, représenté par un oscillateur, mène à la conception et la fabrication d’une spirale piézoélectrique. L’intégration de cette spirale à notre machine thermique forme un générateur thermo-électrique dont les capacités de conversion sont démontrées par la charge d’une capacité. Finalement, la miniaturisation du principe thermo-fluidique SOFHE est rendue possible par la réalisation d’un procédé de fabrication utilisant les techniques MEMS. Des dispositifs miniatures parviennent à exhiber un comportement oscillatoire montrant le potentiel d’intégration de cette technologie. / Abstract : The tremendous technological progresses realized in the last decades allow us to swarm our environment with Wireless Sensors Networks. These WSNs combine the MEMS’ miniature size and low energy consumption, and the powerful Internet communication protocols. This Internet of Things shows great potential in many applications such as industry or housing. For a decade now, the Energy Harvesting community wants to build autonomous WSNs by enabling them to feed off energy wastes. In this work, we study the electricity generation capabilities of a Self-Oscillating Fluidic Heat Engine (SOFHE) and present its characteristic thermodynamic cycle. Our model shows that the SOFHE acts as a mechanical resonator excited by the successive evaporation and condensation processes underwent by the working fluid. These phase changes put a liquid mass in motion, coupled with a vapor spring. The coupling of our heat engine with an electromechanical transducer is studied and leads to a piezoelectric spiral conception and fabrication. Their association forms a thermo-electrical generator able to power and charge an electrical capacitor. Eventually, we demonstrate the miniaturization prospects and integration potential of this SOFHE technology. A micro-fabrication process enables a SOFHE MEMS implementation. Our process includes a deep glass wet etching step as well as a Au-Si eutectic wafer bonding.

Récupération d'énergie thermique

Auto-oscillations

Oscillateur thermofluidique

SOFHE

Spirale piézoélectrique

Procédés MEMS

Collage eutectique

Heat energy harvesting

Thermodynamic cycle

Piezoelectric spiral

MEMS fabrication processes

Eutectic bonding