Spelling suggestions: "subject:"resonant cavities"" "subject:"resonant eavities""
1 |
Étude des mécanismes de diffusion acoustique d'une cavité et d'un réseau à relief périodique et apériodique / Sound scattering mechanisms modelization of a cavity, periodic and aperiodic gratingsKhanfir, Adel 30 November 2012 (has links)
L'objectif de cette étude est de développer un modèle théorique du champ de pression acoustique réfléchi au-dessus d'un réseau constitué de N cavités rectangulaires. Pour cela, une adaptation de la méthode Kobayashi Potentiel (KP) a été effectuée au cas d'une cavité rectangulaire dans un écran rigide à épaisseur non négligeable. Ce modèle ainsi adapté a été généralisé au cas de réseaux contenant plusieurs cavités rectangulaires parallèles, puis étendu au cas de réseaux de cavités rectangulaires non parallèles. Une étude du couplage a été menée pour comprendre la variation de l'interaction acoustique existant entre les cavités en fonction de l'espacement et de la fréquence. Ce modèle a été comparé aux résultats théoriques, issus de la méthode des éléments finis (FEM), et aux résultats expérimentaux obtenus dans une chambre semi-anéchoïque pour une seule cavité, des réseaux de cavités rectangulaires parallèles et non parallèles. La validité du modèle théorique est soutenu par l'accord observé entre les résultats théoriques et expérimentaux / The purpose of this research project was to develop a theoretical model dealing with reflection of acoustic waves over a grating of N rectangular cavities. Thus, the diffracted acoustic fields were determined by adapting the Kobayashi Potential (KP) method to the case of a cavity. Then, this developed model was generalized to the case of parallel rectangular cavities gratings and then extended to the case of non parallel rectangular cavities ones. A study of the coupling was achieved in order to understand the variation in the acoustic interaction between cavities with spacings and frequency. This model was compared with theoretical results obtained from the finite element method (FEM) and experimental results obtained in a semi-anechoic chamber for a single cavity and gratings of parallel and non-parallel rectangular cavities. The validity of the theoretical model is supported by the agreement between the numerical and experimental results observed
|
2 |
Design and performance of resonant cavities for communication systems : the theory and performance of resonant cavities for application in mobile radio and base-stations in the VHF and UHF bands are investigatedAdeniran, S. Adekunle January 1984 (has links)
It is often necessary to operate a number of radio communication channels from a single control room without time-sharing between the various channels. Here it is necessary to operate a number of transmitters and receivers simultaneously from the same base station or mobile unit without interference. The best method to achieve this has been found in the use of filters inserted in the transmission line between the antenna and the transmitter(s) on one hand and the receiver(s) on the other hand. The basic unit employed in the design of microwave filters is usually a cavity resonator of which the most important factors are the Q, insertion loss and resonant frequency. However, a problem which frequently arises with cavity resonators is the accurate determination of these resonant characteristics complicated by the presence of coupling port, materials and various design and geometrical deviations. Such cavities have been investigated in several cases and the results have been generalised, but this investigation has been conducted to examine thoroughly most of the problems being met in present practice. Design and development of some common resonant structures are considered. Emphasis is placed on solutions found to special problems especially regarding complicated boundary conditions. Furthermore, investigation includes methods for optimising resonant parameters such as insertion loss and Q, trading of insertion loss with coupled cavity selectivity, frequency tuning and compensation for frequency variations due to wide ranges of operating temperatures. By comparing Q values obtained in practice with theoretical values, it has been possible to establish an appropriate Q loss budget to as to facilitate accurate prediction of coupled cavity unloaded Q. A satisfactory agreement between theory and practice has been obtained. By application of the results of theoretical analysis and experiment, it is shown that microwave filters can be designed to have a desired insertion loss and off-band attenuation slope. Steps leading to designs of any number of cascaded cavities in a two-port network and, subsequently, multi-port networks are discussed in detail.
|
3 |
Design and performance of resonant cavities for communication systems. The theory and performance of resonant cavities for application-, in mobile radio and base-stations in the VHF and UHF bands are investigated.Adeniran, S. Adekunle January 1984 (has links)
It is often necessary to operate a number of radio communication
channels from a single control room without time-sharing between the
various channels. Here it is necessary to operate a number of transmitters
and receivers simultaneously from the same base station or
mobile unit without interference. The best method to achieve this
has been found in the use of filters inserted in the transmission line
between the antenna and the transmitter(s) on one hand and the receiver(s)
on the other hand.
The basic unit employed in the design of microwave filters is
usually a cavity resonator of which the most important factors are the
Q, insertion loss and resonant frequency. However, a problem which
frequently arises with cavity resonators is the accurate determination
of these resonant characteristics complicated by the presence of coupling
port, materials and various design and geometrical deviations. Such
cavities have been investigated in several cases and the results have
been generalised, but this investigation has been conducted to examine
thoroughly most of the problems being met in present practice. Design
and development of some common resonant structures are considered.
Emphasis is placed on solutions found to special problems especially
regarding complicated boundary conditions. Furthermore, investigation
includes methods for optimising resonant parameters such as insertion
loss and Q, trading of insertion loss with coupled cavity selectivity,
frequency tuning and compensation for frequency variations due to wide
ranges of operating temperatures. By comparing Q values obtained in
practice with theoretical values, it has been possible to establish an
appropriate Q loss budget to as to facilitate accurate prediction of coupled
cavity unloaded Q. A satisfactory agreement between theory and practice
has been obtained.
By application of the results of theoretical analysis and experiment,
it is shown that microwave filters can be designed to have a desired
insertion loss and off-band attenuation slope. Steps leading to
designs of any number of cascaded cavities in a two-port network and,
subsequently, multi-port networks are discussed in detail.
|
4 |
Modelagem de maquinas de solda por indução eletromagnetica em RF / Modeling of welding machines for electromagnetic induction in RFJeronimo, Joice Luiz 13 August 2018 (has links)
Orientador: Hugo Enrique Hernandez Figueroa / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Eletrica e de Computação / Made available in DSpace on 2018-08-13T12:10:33Z (GMT). No. of bitstreams: 1
Jeronimo_JoiceLuiz_M.pdf: 4749050 bytes, checksum: f44d530638f8a8121e171afc306321ff (MD5)
Previous issue date: 2009 / Resumo: Este trabalho trata do estudo de máquinas industriais de solda por indução eletromagnética na faixa de Rádio Freqüência (RF), visando modelos robustos baseados em circuitos de parâmetros concentrados. Tipicamente as máquinas industriais para a aplicação em questão, apresentam três estágios; a fonte (geração de energia eletromagnética), blindagem e filtragem (através de uma cavidade), e alimentação da carga. Por se tratar de um equipamento de alta potência (dezenas de KVs), a fonte consiste num oscilador à válvula, na faixa 20-50 MHz. A fonte excita uma cavidade que ressoa e funciona como um armazenador dessa radiação eletromagnética e um filtro de freqüência. Finalmente a energia da cavidade é extraída através de dispositivo análogo a uma linha de transmissão e colocado em contato com a carga, isto é, o material a ser soldado. Os modelos propostos fazem uso de circuitos equivalentes eficientes obtidos para as válvulas e as cavidades eletromagnéticas utilizadas, e foram validados através de testes experimentais minuciosos aplicados a uma máquina de fabricação nacional, líder de vendas no mercado latino-americano. / Abstract: This work is related to the study of electromagnetic weld industrial machines operating in radio frequency band aiming robust models based on concentrated parameters circuits. Typically, those machines have three steps: the power source (electromagnetic energy generation), shielding and filtering (through cavity) and load power supply. Since the equipment demands high power (dozen of KVs), the power source consists of a valve oscillator of 20-50MHz bandwidth. The power source excites a cavity that resonants and works like a storing of electromagnetic radiation and a frequency filter. Finally, the cavity energy is extracted through a device that works like a transmission line and sent to the load, that means, the material to be welded. The proposed models use efficient equivalent circuits found for the machine valves and cavities, and they were validated through detailed experiments on a machine produced for a Brazilian company, leader of the Latin American market. / Mestrado / Telecomunicações e Telemática / Mestre em Engenharia Elétrica
|
5 |
Two-Dimensional Photonic Crystals in InP-based MaterialsMulot, Mikaël January 2004 (has links)
Photonic crystals (PhCs) are structures periodic in thedielectric constant. They exhibit a photonic bandgap, i.e., arange of wavelengths for which light propagation is forbidden.Engineering of defects in the PhC lattice offers new ways toconfine and guide light. PhCs have been manufactured usingsemiconductors and other material technologies. This thesisfocuses on two-dimensional PhCs etched in InP-based materials.Only recently, such structures were identified as promisingcandidates for the realization of novel and advanced functionsfor optical communication applications. The primary focus was on fabrication and characterization ofPhC structures in the InP/GaInAsP/InP material system. Thedemands on fabrication are very high: holes as small as100-300nm in diameter have to be etched at least as deep as 2µm. Thus, different etch processes had to be explored andspecifically developed for InP. We have implemented an etchingprocess based on Ar/Cl2chemically assisted ion beam etching (CAIBE), thatrepresents the state of the art PhC etching in InP. Different building blocks were manufactured using thisprocess. A transmission loss of 10dB/mm for a PhC waveguide, areflection of 96.5% for a 4-row mirror and a record qualityfactor of 310 for a 1D cavity were achieved for this materialsystem. With an etch depth of 4.5 µm, optical loss wasfound to be close to the intrinsic limit. PhC-based opticalfilters were demonstrated using (a) a Fabry-Pérot cavityinserted in a PhC waveguide and (b) a contra-directionalcoupler. Lag effect in CAIBE was utilized positively to realizehigh quality PhC taper sections. Using a PhC taper, a couplingefficiency of 70% was demonstrated from a standard ridgewaveguide to a single line defect PhC waveguide. During the course of this work, InP membrane technology wasdeveloped and a Fabry-Pérot cavity with a quality factorof 3200 was demonstrated. Keywords:photonic crystals, photonic bandgap materials,indium phosphide, dry etching, chemically assisted ion beametching, reactive ion etching, electron beam lithography,photonic integrated circuits, optical waveguides, resonantcavities, optical filtering, finite difference time domain,plane wave expansion.
|
6 |
Two-Dimensional Photonic Crystals in InP-based MaterialsMulot, Mikaël January 2004 (has links)
<p>Photonic crystals (PhCs) are structures periodic in thedielectric constant. They exhibit a photonic bandgap, i.e., arange of wavelengths for which light propagation is forbidden.Engineering of defects in the PhC lattice offers new ways toconfine and guide light. PhCs have been manufactured usingsemiconductors and other material technologies. This thesisfocuses on two-dimensional PhCs etched in InP-based materials.Only recently, such structures were identified as promisingcandidates for the realization of novel and advanced functionsfor optical communication applications.</p><p>The primary focus was on fabrication and characterization ofPhC structures in the InP/GaInAsP/InP material system. Thedemands on fabrication are very high: holes as small as100-300nm in diameter have to be etched at least as deep as 2µm. Thus, different etch processes had to be explored andspecifically developed for InP. We have implemented an etchingprocess based on Ar/Cl<sub>2</sub>chemically assisted ion beam etching (CAIBE), thatrepresents the state of the art PhC etching in InP.</p><p>Different building blocks were manufactured using thisprocess. A transmission loss of 10dB/mm for a PhC waveguide, areflection of 96.5% for a 4-row mirror and a record qualityfactor of 310 for a 1D cavity were achieved for this materialsystem. With an etch depth of 4.5 µm, optical loss wasfound to be close to the intrinsic limit. PhC-based opticalfilters were demonstrated using (a) a Fabry-Pérot cavityinserted in a PhC waveguide and (b) a contra-directionalcoupler. Lag effect in CAIBE was utilized positively to realizehigh quality PhC taper sections. Using a PhC taper, a couplingefficiency of 70% was demonstrated from a standard ridgewaveguide to a single line defect PhC waveguide.</p><p>During the course of this work, InP membrane technology wasdeveloped and a Fabry-Pérot cavity with a quality factorof 3200 was demonstrated.</p><p><b>Keywords:</b>photonic crystals, photonic bandgap materials,indium phosphide, dry etching, chemically assisted ion beametching, reactive ion etching, electron beam lithography,photonic integrated circuits, optical waveguides, resonantcavities, optical filtering, finite difference time domain,plane wave expansion.</p>
|
7 |
Auslegung von Mikrowellen-Thermoprozess-Anlagen unter Nutzung von hochfrequenz-technischen PrinzipienReichmann, Markus 18 April 2011 (has links) (PDF)
Um der Mikrowellenerwärmung als Single- oder Hybridanwendung im industriellen Ofenbau ein weiteres Anwendungsspektrum zu eröffnen, wird dem Anlagenkonstrukteur im Rahmen dieser Arbeit eine Aufstellung von Entwicklungsprioritäten und Konstruktionshinweisen übergeben. Für eine energieeffiziente Ausnutzung des technologischen Potenzials wird hierbei nicht - wie in der Vergangenheit - die Feldstärkenverteilung, sondern das Reflexionsverhalten in den Vordergrund gestellt.
Durch die Entwicklung und den Aufbau eines Messplatzes zur Bestimmung temperaturspezifischer Dielektrizitätsparameter konnte die Realitätsnähe der Simulation für die anwendungsorientierte Applikatorentwicklung gesteigert werden.
Die Anwendbarkeit der Auslegungskriterien wird im Rahmen der Projektierung und des Aufbaus einer Beispielanlage zur Entbinderung von keramischen Grünkörpern und bei der Entwicklung zahlreicher mikrowellenspezifischer Anlagenbauteile verifiziert.
|
8 |
Auslegung von Mikrowellen-Thermoprozess-Anlagen unter Nutzung von hochfrequenz-technischen Prinzipien: am Beispiel eines Entbinderungsofens für keramische GrünkörperReichmann, Markus 18 April 2011 (has links)
Um der Mikrowellenerwärmung als Single- oder Hybridanwendung im industriellen Ofenbau ein weiteres Anwendungsspektrum zu eröffnen, wird dem Anlagenkonstrukteur im Rahmen dieser Arbeit eine Aufstellung von Entwicklungsprioritäten und Konstruktionshinweisen übergeben. Für eine energieeffiziente Ausnutzung des technologischen Potenzials wird hierbei nicht - wie in der Vergangenheit - die Feldstärkenverteilung, sondern das Reflexionsverhalten in den Vordergrund gestellt.
Durch die Entwicklung und den Aufbau eines Messplatzes zur Bestimmung temperaturspezifischer Dielektrizitätsparameter konnte die Realitätsnähe der Simulation für die anwendungsorientierte Applikatorentwicklung gesteigert werden.
Die Anwendbarkeit der Auslegungskriterien wird im Rahmen der Projektierung und des Aufbaus einer Beispielanlage zur Entbinderung von keramischen Grünkörpern und bei der Entwicklung zahlreicher mikrowellenspezifischer Anlagenbauteile verifiziert.
|
9 |
Composants céramiques 3D innovants pour des applications spatiales de télécommunications millimétriques en bandes Q et V / Advanced technologies for millimeterwave integrated filters in Q and V bandsDrissi, Mohamed Khalil 15 December 2016 (has links)
Ce mémoire est consacré au développement de technologies de filtrage novatrices qui apportent un gain en performance permettant de répondre aux besoins de filtrage pour télécommunications spatiales à moyen et long termes. Il s’inscrit dans le projet ANR ATOMIQ coordonné par Thales Alenia Space ayant comme partenaires le laboratoire SPCTS et la société 3D CERAM. Le premier chapitre est constitué d’une étude bibliographique sur les filtres en bande Q et V ainsi que les technologies de fabrication 3D. Le deuxième chapitre est consacré à l’élaboration d’une nouvelle formulation d’alumine très pure à faible pertes et stable en température. Le troisième chapitre présente une conception de filtres hyperfréquences en bande Q et V à base de cavités résonantes diélectriques. Le quatrième chapitre concerne la fabrication des filtres par usinage en cru ainsi que la présentation des différents démonstrateurs fabriqués par stéréolithographie et moulage basse pression. Il présente aussi des solutions de correction post-fabrication par tir laser. Ce travail est original par l’utilisation de la stéréolithographie céramique 3D ainsi que du moulage basse pression pour fabriquer des filtres hyperfréquences de petites tailles en bande Q et V. / This thesis focus on the development of innovative filtering technologies that enhance the performance to meet the filtering requirements for spacial communications. It is part of the ANR project ATOMIQ coordinated by Thales Alenia Space with partners (SPCTS 3D CERAM). The first chapter consists of a literature review on the Q and V band filters as well as 3D manufacturing technologies. The second chapter is devoted to the development of a new formulation of highly pure, low losses and temperature stable alumina. The third chapter presents a microwave filter design in Q and V band based on a dielectric resonant cavity. The fourth chapter is about the manufacturing of filters and presentation of various demonstrators manufactured by stereolithography and low pressure molding. It also provides a post-production correction solutions based on laser shoots. This work is original because, to the best of our knowledge, 3D ceramic stereolithography and the low pressure molding have not been used to produce small sizes Q and V band microwave filters.
|
10 |
Innovative production of nuclear fuel by microwave internal gelationCabanes Sempere, Maria 02 September 2013 (has links)
El continuo af'an por reducir la cantidad de act'¿nidos minoritarios (MA) procedentes del combustible quemado en los reactores de agua ligera (Light Water Reactor, LWR) y de esa forma reducir la radiotoxicidad, ha llevado a desarrollar nuevos conceptos de combustible nuclear. El nuevo combustible por empaquetamiento de esferas (Sphere-Pac, SP) ofrece la oportunidad de reintroducir los MA en una matriz y quemarlos en un reactor r'apido de neutrones, donde se facilitan ciclos mu'ltiples por transmutaci'on de elemen- tos. Este combustible se puede utilizar tambi'en en un sistema subcr'¿tico r'apido de neutrones, es decir, un sistema nuclear accionado por un acelera- dor de part'¿culas (Accelerator Driven System, ADS), donde la subcriticidad (seguridad de parada del reactor) permite utilizar combustibles con mayor contenido de MA que en un reactor normal, reduciendo eficazmente en un solo paso la radiotoxicidad.
El combustible SP se produce a partir de una soluci'on base (formada por metales y elementos qu'¿micos) mediante un proceso de gelificaci'on in- terna. Este proceso garantiza una buena homogeneidad del producto final y un riesgo de contaminaci'on mucho menor si se compara con la fabricaci'on cl'asica de pellets (combustible comprimido), puesto que se evita el uso de prensas y amoladoras. La gelificaci'on interna es una reacci'on qu'¿mica acu- osa que se produce al calentar la soluci'on hasta 80 ± 5¿ C. Cuando se realiza el proceso por calentamiento electromagn'etico, se observan algunas venta- jas con respecto al calentamiento tradicional por conducci'on (contacto de la muestra con aceite de silicio precalentado): se evita la etapa de reciclado del aceite y de los disolventes org'anicos necesarios para eliminar el aceite de la superficie de las part'¿culas producidas. En la unidad de gelificaci'on in- terna por microondas (Microwave Internal Gelation, MIG), las microondas representan una alternativa mucho m'as simple y segura: el calentamiento volum'etrico sin contacto facilita la producci'on a distancia del combustible en celdas calientes y adem'as reduce los residuos de l'¿quido contaminado.
Esta tesis se enmarca dentro del proyecto Platform for Innovative Nu- clear FuEls (PINE), que tiene como objetivo fundamental la producci'on de combustible SP por MIG. En el sistema MIG, el tiempo de calentamiento es muy corto (del orden de decenas de milisegundos), por lo que se deben optimizar los par'ametros que contribuyen al calentamiento por microondas y es necesario conocer en profundidad la interacci'on entre las microondas y las muestras.
En la primera parte de este trabajo se investiga un modelo t'ermico basado en diferencias finitas en el dominio del tiempo (FDTD), el cual es capaz de determinar, en cada instante durante el proceso de calentamiento, el comportamiento t'ermico de un punto definido dentro del material que se calienta. Adem'as se presenta una descripci'on detallada de los par'ametros m'as relevantes del modelo, incluyendo las condiciones de contorno (entre ellas la convecci'on). Por otra parte, se implementa anal'¿ticamente y se valida con diferentes t'ecnicas: una basada en teor'¿a de la f'¿sica, otra basada en la herramienta de ecuaciones diferenciales parciales (PDEtools) y la u'ltima basada en ejemplos encontrados en la literatura.
En segundo lugar, se investigan los posibles disen¿os de cavidades de microondas para su aplicaci'on en MIG. Tanto las cavidades (selecci'on de los modos, frecuencia de resonancia, factores de calidad, etc.) como su posterior caracterizaci'on, se detallan con el objetivo de especificar el acoplamiento de energ'¿a. Los mecanismos de transferencia de energ'¿a de las cavidades se explican utilizando el m'etodo de perturbaci'on, con el que adem'as se analizan las p'erdidas de la cavidad cuando se coloca una muestra diel'ectrica en su interior. Con el modelo de transferencia de energ'¿a desar- rollado, se obtiene la tasa de generaci'on de calor por microondas, que se aplica al modelo t'ermico FDTD mencionado anteriormente. Los resultados anal'¿ticos demuestran la viabilidad de producir esferas gelificadas por MIG.
Seguidamente se introducen los principales par'ametros relacionados con el calentamiento de un material por microondas, es decir, las propiedades diel'ectricas. Se desarrolla un nuevo procedimiento que permite medir estas propiedades en gotas que caen libremente a trav'es de una cavidad de mi- croondas. Se presenta el montaje experimental, cuya viabilidad se prueba a trav'es de diferentes experimentos. Las propiedades diel'ectricas medidas se incluyen en los modelos (perturbacional y t'ermico) con la intenci'on de determinar la potencia absorbida por la sustancia (en forma de gotas) y la temperatura que alcanza.
En la u'ltima parte se presenta la implementaci'on del sistema MIG apli- cada al proyecto PINE, fundamental para la pr'actica de calentamiento (basado en frecuencias altas) dentro del laboratorio. Las propiedades de cada dispositivo se evaluan para realizar un estudio de potencia antes del ensamblaje del sistema MIG. De esa forma se evitan fallos al poner el sis- tema en funcionamiento. Adem'as se aportan las t'ecnicas experimentales y los resultados. La producci'on con 'exito de esferas gelificadas demuestra, sin duda, el uso favorable de las microondas en la producci'on de combustible SP por gelificaci'on interna. / In the continuous aim to reduce the amount of minor actinides (MA) from
the spent fuel of Light Water Reactors (LWR) and therefore reduce its
radiotoxicity (radioactive toxicity), new nuclear fuel concepts have been
developed. Sphere-Pac (SP) fuel gives the opportunity to reintroduce the
MA in a fuel matrix and to burn them in a fast reactor, which facilitates a
multi-cycle because of its breeding feature, or in a subcritical fast system,
i.e. an Accelerator Driven System (ADS) where its sub-criticality allows
higher MA contents than a normal fast reactor reducing efficiently the
radiotoxicity in one step.
SP fuel is produced from the base solution (already containing all the
elements) by internal gelation, which guarantees a good material homo-
geneity and a lower contamination risk compared to the classical pellet
fabrication, avoiding presses and grinding machines. The internal gelation
is an aqueous chemical reaction occurring when the solution is heated up
to 80 ± 5¿C. When performing the internal gelation process with electro-
magnetic heating, some advantages appear with respect to the traditionally
heating through conduction by contact of the sample with hot silicon oil:
the recycling step of the oil and the organic solvents necessary to clean the
particles from oil are avoided. In the Microwave Internal Gelation (MIG)
unit, the microwaves represent a much simpler and safer alternative: the
contactless volumetric heating facilitates the remote production of the fuel
in hot cells and furthermore reduces the contaminated liquid waste.
The fuel related project called Platform for Innovative Nuclear FuEls
(PINE), in which this thesis is embedded, aims for the production of SP-
fuel by MIG. In the MIG system, the heating time is very short (in the
order of tens of milliseconds), therefore the microwave heating parameters
have to be optimized and a good knowledge of the interaction between the
microwaves and the samples must be achieved.
In the first part of this dissertation a finite difference time domain
(FDTD) thermal model capable to determine over each instant about the
thermal behaviour of a definite point inside a material during heat process-
ing is investigated. A detailed overview of the most relevant parameters
on the model including the boundary conditions (e.g. convection) is pre-
sented. Furthermore, the model is analytically implemented and validated with different techniques: a theoretical based physically validation, a par-
tial differential equations (PDEtools) based validation and a validation with
examples from the literature.
Secondly, possible microwave cavity designs for MIG are researched.
The cavities (selection of modes, resonant frequency, Q-factor, etc.) and
its subsequent characterization for the coupling of energy are explained.
Furthermore, the power transfer mechanisms of the cavities are explained
using the perturbation method to analyse the losses when a dielectric sam-
ple is placed inside a cavity. The developed power transfer model delivers
the microwave heat generation rate which is applied to the FDTD thermal
model mentioned in the previous paragraph. The analytical results provide
a positive impression about the feasibility of producing gelated spheres by
MIG.
Next, the main parameters dealing with the heating of a material by
microwaves are introduced. A new procedure that enables the measure-
ment of dielectric properties of aqueous droplets freely falling through a
microwave cavity is developed. The experimental setup is presented and
several experiments prove its feasibility. The measured dielectric properties
are afterwards included in the perturbation and thermal models with the
main intention of determining the absorbed power by the material in form
of drops and the reached temperature.
In the last part the MIG system for the laboratory practice of the high
frequency heating applied to the PINE project is implemented. Each device
is characterized for a power study precedent to the MIG system assembly,
avoiding then failures when putting the system into operation. In addition,
the experimental techniques and the results are reported. Successful pro-
duction of gelated spheres shows the favourable usage of microwave for the
production of SP-fuel by internal gelation. / Cabanes Sempere, M. (2013). Innovative production of nuclear fuel by microwave internal gelation [Tesis doctoral]. Editorial Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/31641
|
Page generated in 0.0633 seconds