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1	Micro loop heat pipe evaporator coherent pore structures Alexseev, Alexandre Viktorovich 17 February 2005 (has links) Loop heat pipes seem a promising approach for application in modern technologies where such thermal devices as cooling fans and radiators cannot satisfy overall requirements. Even though a loop heat pipe has a big potential to remove the thermal energy from a high heat flux source, the heat removal performance of heat pipes cannot be predicted well since a first principles of evaporation has not been established. An evaporation model based on statistical rate theory has been recently suggested by Ward and developed for a single pore by Oinuma. A loop heat pipe with coherent pore wick structure has been proposed as a design model. To limit product development risk and to enhance performance assurance, design model features and performance parameters have been carefully reviewed during the concept development phase and have been deliberately selected so as to be well-founded on the limited existing loop heat pipe knowledge base. A first principles evaporation model has been applied for evaporator geometry optimization. A number of iteration calculations have been performed to satisfy design and operating limitations. A set of recommendations for design optimization has been formulated. An optimal model has been found and proposed for manufacture and experimental investigation. loop heat pipe evaporator coherent pore evaporation
2	Design and Experimental Analysis of a Loop Heat Pipe for Thermal Control of Aircraft Engine Equipment / Conception et analyse expérimentale d'une boucle diphasique passive LHP pour le contrôle thermique des composants intégrés dans les moteurs aéronautiques Pagnoni, Filippo 11 April 2019 (has links) Ces travaux de thèse sont focalisés sur le développement d’une boucle diphasique LHP pour le contrôle thermique de composants intégrés dans les moteurs aéronautiques. L’étude concerne les compartiments situés à l’intérieur de la nacelle, en lien avec les challenges thermiques des moteurs de future génération. Tout d’abord, une étude de faisabilité a été menée, basée sur une évaluation de l’environnement thermique, une analyse des contraintes d’intégration et une première identification d’un couple fluide de travail-matériau de construction. En ce qui concerne ce dernier aspect, l’eau et le DowthermTM J ont été identifiés comme les meilleurs candidats pour leur utilisation avec les alliages souhaités pour cet environnement. D’un côté, le point triple élevé de l’eau a obligé la vérification de la tenue mécanique du milieu capillaire mouillé à des cycles de gel/dégel. Le milieu poreux fritté en titane a montré une excellente résistance mécanique et il est resté parfaitement intact après plus de 1500 cycles. D’un autre côté, vu le manque d’informations concernant la compatibilité du DowthermTM J avec les matériaux sélectionnés, des tests de compatibilité ont été effectués avec trois thermosiphons en parallèle, et ont montré un taux de génération de gaz non condensables déjà à faible température. Pour cette raison, la compatibilité entre le DowthermTM J et les matériaux a été jugé non satisfaisante et le fluide a été rejeté. L’étape suivante a été la conception d’un prototype de boucle LHP. Des outils numériques robustes ont été développés pour la validation finale : un modèle 0D pour la boucle entière ainsi qu’un modèle couplé 1D - 2D du condenseur. Le prototype de LHP a été construit et testé sous différentes conditions opératoires. Une quantité de gaz non condensable a été observée initialement, due à la passivation des surfaces intérieures à la boucle. Néanmoins, les résultats expérimentaux ont montré que la boucle répond aux cahiers de charge thermique, même en présence de ces gaz,étant capable de fonctionner sous hautes températures et haute pression. La génération de gaz s’est arrêtée après un certain nombre d’heures cumulées de fonctionnement ; pourtant, les inspections internes à l’évaporateur après les tests ont montrés une dégradation significative de l’état de surface, due aux réactions chimiques entre le fluide de travail et les matériaux de la boucle. Les résultats de ces travaux de thèse constituent une étape fondamentale vers le développement d’une boucle LHP pour le contrôle thermique de composants intégrés dans la nacelle. Des informations essentielles à la conception des prototypes de future génération sont fournies, vers la validation et la certification des LHP pour leur utilisation dans cet environnement. / In this work, the development of a Loop Heat Pipe (LHP) for aircraft nacelle thermal management is presented. The study is focused on engine compartments and integrated equipment applications, according to the upcoming thermal management challenges in the next generation of engines. First, a feasibility study was performed, analyzing the thermal environment, the integration constraints and the identification of suitable working fluid construction material pairs. As for the latter aspect, water and DowthermTM J were identified as most suitable candidates with the lightweight aeronautical alloys considered for this environment. On one hand, the high triple point of water obliged to verify the wick mechanical resistance to repeated freezing cycles when soaked into pure water. On the other hand, compatibility tests were performed between DowthermTM J and the selected alloys, due to the lack of related data. In the former, the sintered titanium wick provided an excellent stiffness and it remained perfectly intact after more than 1500 cycles. In the latter, the thermal tests performed on parallel thermosyphon shave clearly shown the generation of non-condensable gases (NCG) inside all the samples starting from low operating temperatures. As a result, the compatibility of DowthermTM J was considered not fully satisfactory and this fluid was discarded. The next step concerned the design of the titanium/water LHP prototype. Robust numerical tools were developed for the final design validation: a simplified 0D nodal model for the entire device and a coupled 1D and 2D condenser model representation. The LHP prototype was manufactured and tested in different operating conditions. A significant amount of NCG was initially generated inside the device, due top assivation of the internal surfaces. Nonetheless, the experimental results demonstrated the LHP capability to satisfy the thermal requirements, even in presence of NCG, with standing high operating temperatures and pressures. Although the gas generation rate became negligible after several hours of tests, internal inspections performed at the end of the test revealed a deep alteration of the internal surface state, due to the chemical reactions with the working fluid. The results of this work represent an important milestone for the development of a LHP for aircraft nacelle applications. Essential information for the design of future generations of prototypes are provided, toward the validation and certification of LHP for nacelle thermal management. Boucle diphasique Nacelle turboréacteur Loop heat pipe Aircraft nacelle
3	DEVELOPMENT OF A MICRO LOOP HEAT PIPE, A NOVEL MEMS SYSTEM BASED ON THE CPS TECHNOLOGY SHUJA, AHMED 07 July 2003 (has links) No description available. MEMS loop heat pipe macro porous silicon micro fabrication
4	MEMS-BASED DEVELOPMENT OF A SILICON CPS WICK FOR LOOP HEAT PIPE APPLICATIONS MANTRAVADI, NARESH VENKATA 11 October 2001 (has links) No description available. coherent porou silicon loop heat pipe mems micromachinery
5	Fundamental study of evaporation model in micron pore Oinuma, Ryoji 15 November 2004 (has links) As the demand for high performance small electronic devices has increased, heat removal from these devices for space use is approaching critical limits. A heat pipe is a promising device to enhance the heat removal performance due to the phase change phenomena for space thermal management system. Even though a heat pipe has a big potential to remove the thermal energy from a high heat flux source, the heat removal performance of heat pipes cannot be predicted well since the first principle of evaporation has not been established. The purpose of this study is to establish a method to apply the evaporation model based on the statistical rate theory for engineering application including vapor-liquid-structure intermolecular effect. The evaporation model is applied to the heat pipe performance analysis through a pressure balance and an energy balance in the loop heat pipe. loop heat pipe evaporation model intermolecular forces statistical rate theory coherent porous material
6	Steady State Mathematical Modeling of Non-Conventional Loop Heat Pipes: A Parametric and a Design Approach Remella Siva Rama, Karthik January 2012 (has links) No description available. Mechanical Engineering Entrainment Loop Heat Pipe LED cooling Parametric model Design model
7	LOOP HEAT PIPE (LHP) MODELING AND DEVELOPMENT BY UTILIZING COHERENT POROUS SILICION (CPS) WICKS HAMDAN, MOHAMMAD OMAR 17 April 2003 (has links) No description available. LHP LOOP HEAT PIPE CPS CAPILLARY PRESSURE CPL - CAPILLARY PUMPED LOOP
8	Proof of Operation in a Planar Loop Heat Pipe (LHP) Based on CPS Wick Suh, Junwoo January 2005 (has links) No description available. Engineering, Mechanical Electronic Cooling Microscale Heat Pipes Loop Heat Pipe Thermosyphon Coherent Porous Silicon Wick
9	Development of Microfluidic Packaging Strategies, with Emphasis on the Development of a MEMS Based Micro Loop Heat Pipe Medis, Praveen S. January 2005 (has links) No description available. Microfluidic Packaging Loop Heat Pipe LHP Lab on a chip Ultrasonic impact grinding Ultrasonic for MEMS MEMS
10	Material and Processing Development Contributions Toward the Development of a MEMS Based Micro Loop Heat Pipe Shuja, Ahmed A. 03 July 2007 (has links) No description available. Loop Heat Pipe Micro Scale Heat Transfer Coherent Porous Silicon Electronics Cooling two phase cooling

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