Academic literature on the topic 'Aluminum heat pipe'
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Journal articles on the topic "Aluminum heat pipe"
Sun, Youhong, Xiaofeng Wang, Baochang Liu, Dali Ding, and Qingnan Meng. "Inverse solution to heat transfer coefficient during heat assembly of aluminum alloy drill pipes." Advances in Mechanical Engineering 9, no. 7 (July 2017): 168781401771497. http://dx.doi.org/10.1177/1687814017714970.
Full textSriram, V., and B. Kanimozhi. "Investigation of the Effect of Different Materials on Uniform Heat Distribution Over a Solar Collector Pipe." Journal of Computational and Theoretical Nanoscience 17, no. 5 (May 1, 2020): 2021–23. http://dx.doi.org/10.1166/jctn.2020.8842.
Full textTake, Koichiro, and Ralph L. Webb. "Thermal Performance of Integrated Plate Heat Pipe With a Heat Spreader." Journal of Electronic Packaging 123, no. 3 (April 1, 2000): 189–95. http://dx.doi.org/10.1115/1.1348010.
Full textZhu, Wen Feng, Jie Wang, Pei Jian Lin, and Bing Yang Zhang. "Numerical Simulation of Influence of Different Heat Source Models on Temperature Field of Aluminum-Alloy Ring Weld Seam." Applied Mechanics and Materials 456 (October 2013): 216–19. http://dx.doi.org/10.4028/www.scientific.net/amm.456.216.
Full textCheng, Po Jen, David T. W. Lin, Chi Chang Wang, Wu Man Liu, and Chai Wei Chang. "Design of the Cooling Module of LEDs Based on the Aluminum-Acetone Flat Plate Heat Pipe." Applied Mechanics and Materials 764-765 (May 2015): 244–48. http://dx.doi.org/10.4028/www.scientific.net/amm.764-765.244.
Full textHoward, A. H., and G. P. Peterson. "Investigation of a Heat Pipe Array for Convective Cooling." Journal of Electronic Packaging 117, no. 3 (September 1, 1995): 208–14. http://dx.doi.org/10.1115/1.2792093.
Full textBai, Li, and Tan Liu. "Research on Different Heat Transfer Characteristics of the Dirt on the Pipe." Applied Mechanics and Materials 644-650 (September 2014): 5179–82. http://dx.doi.org/10.4028/www.scientific.net/amm.644-650.5179.
Full textKou, Zhi Hai, Min Li Bai, and Hong Wu Yang. "Thermal Performance of a Novel Flat Heat Pipe with Integral Micro-Grooved Wick for Energy Saving." Advanced Materials Research 648 (January 2013): 202–5. http://dx.doi.org/10.4028/www.scientific.net/amr.648.202.
Full textKuo, Chun-Ching, and Huei Chu Weng. "Heat Transfer Enhancement in Gravity Heat Pipes Using AAO Nanostructure Generated on Condenser Section Inner Surface." Processes 9, no. 10 (October 14, 2021): 1827. http://dx.doi.org/10.3390/pr9101827.
Full textWu, Hai Bao, Ji Zhen Li, De Fu Li, De Gui Liu, and Guo Qiang Chai. "Microstructures and Properties of Spinning for Silicon Carbide Particle Reinforced Aluminum Composite." Materials Science Forum 944 (January 2019): 571–80. http://dx.doi.org/10.4028/www.scientific.net/msf.944.571.
Full textDissertations / Theses on the topic "Aluminum heat pipe"
Meratian, Isfahani Mahmood. "Thermal analysis of aluminum foundry alloys by a novel heat pipe probe." Thesis, McGill University, 1995. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=28846.
Full textThermal analysis is a technique whereby a small quantity of a melt is allowed to solidify while its cooling curve is recorded. Analysis of the cooling curve with standard mathematical algorithms allows one to determine a number of useful parameters that characterize the liquid and solid states of the material. In aluminum-silicon casting alloys thermal analysis is often used to assess the grain size and degree of eutectic modification of the alloy before pouring.
A novel probe has been developed for conducting thermal analysis of aluminum alloy melts. The probe, which resides in the melt, need not be withdrawn as it solidifies a small sample (i.e. button) at a predetermined cooling rate. Once the cooling curve results have been acquired, the probe can be instructed to remelt the frozen button and await instructions for analyzing a fresh sample.
The operating principle of this novel device is based on heat pipe technology. In simple terms, a heat pipe consists of a condenser and an evaporator which contain a relatively small quantity of working substance fluid. As heat is absorbed by the evaporator, the liquid phase of the working substance is vaporized and subsequently condensed on the condenser walls from which heat is extracted.
It has been shown that the designed probe, which is classified as a gas loaded annular thermosyphon, is completely workable in the range of conditions typically encountered in the thermal analysis of aluminum alloys. The thermal analysis results obtained with this new technique are in a good agreement with those of conventional thermal analysis. In addition, the new method is applicable to a wider range of operating conditions and is easier to use. Based on the semi-continuous nature of the new method, it does not need pre-preparation (materials, labour, pre-heating, thermocouple installation for each test, isolation of the sampling cup, etc.) to start thermal analysis. Also, from a cooling rate point of view, the system is well controllable. Moreover, it is shown that the probe is simple in construction, easy to use, and intelligent enough to provide semi-continuous thermal analysis. There are no consumable materials and moving parts.
Thermal analysis results are reported for pure aluminum, hypoeutectic aluminum silicon (356) and eutectic aluminum silicon (413) casting alloys. Agreement in the results between the new and conventional systems is shown to be excellent. Finally, a heat transfer/solidification model of the heat pipe thermal analysis probe is derived and validated.
Malan, Daniel Johannes. "Latent heat thermal energy storage for solar water heating using flat heat pipes and aluminum fins as heat transfer enhancers." Thesis, Stellenbosch : Stellenbosch University, 2014. http://hdl.handle.net/10019.1/96140.
Full textENGLISH ABSTRACT: Solar energy is a time dependent, high-temperature radiant energy resource. The utility of a solar thermal energy system increases if the hot temperature source is available when it is needed most. This is realized by the thermal storage of the solar energy. Thermal storage gives greater versatility to a solar energy system by decoupling the heat source from the heat sink. A large quantity of energy may be stored during the melting process in a phase change material (PCM) within a small temperature range. This molten PCM can then deliver its absorbed heat at a constant temperature in a heating application. In this study a phase change storage system (PCS) is developed and proposed for a solar water heating application. This PCS system stores more heat per unit mass than would be possible with water across the same temperature range. The heat transfer rate in and out of many PCMs is slow because of the low thermal conductivity of the PCM. However, heat transfer enhancers (HTE), such as heat pipes and fins may be added to enhance heat absorption and heat removal rates. Heat pipes have the inherent capability to transfer heat at high rates across large distances, even where the temperature difference is small. In this thesis a description is given of a PCS system consisting of paraffin wax as the PCM and which uses rectangular heat pipes in conjunction with aluminium fins to enhance heat transfer. The storage design is modular and each module has the characteristic that enhanced heat transfer in and out of the PCM is possible when the module is heated or cooled. It also has the capability to quickly absorb or alternatively to supply heat at a nearly constant temperature during the phase change of the module. A rectangular module was designed and built. The module was then analysed under controlled heat absorption and heat removal cycles. The heat up experiment involved an electrical kettle as the hot temperature source. The heat sink was a mains water heat exchanger. The experimental results were compared to those of a transient numerical model, which calculates theoretically how the module will perform thermally under the given test conditions. The numerical model of the experimental set-up was validated when it was found that the numerical model results resemble the experimental results. The numerical model was then adapted to simulate a novel solar water heater (SWH) with an additional PCS container. The improvement over previous designs is that the additional storage container can be heated to a higher temperature than the allowable geyser temperature. The system also heats up and cools down at a faster rate than would be possible without the HTEs. From the numerical simulation the size and performance of such a system is determined. This numerical analysis indicated that a phase change storage system in a SWH application will increase the hot water delivered by a given solar collector and geyser by increasing the storage capacity and by heating up the geyser overnight for early morning hot water use.
AFRIKKANSE OPSOMMING: Son energie is ‘n tyd afhanklike, hoë temperatuur radiasie energiebron. Die bruikbaarheid van ‘n sontermiese energie sisteem verhoog indien die hoë temperatuur bron beskikbaar is wanneer dit die meeste benodig word. Dit kan verwesenlik word deur die sonenergie termies te stoor. Termiese storing bied groter veelsydigheid aan ‘n sontermiese stelsel deur effektief die hittebron te ontkoppel van die hitte sink. ‘n Groot hoeveelheid energie kan, gedurende die smeltingsproses in ‘n faseveranderingsmateriaal binne ‘n nou temperatuurband gestoor word. Hierdie gesmelte materiaal kan weer op sy beurt in die waterverhittingstoepassing, die geabsorbeerde hitte teen ‘n konstante temperatuur oordra. In hierdie studie word ‘n sonwaterverwarmer stelsel wat aangepas is deur ‘n addisionele latente hittestoor daaraan te heg, voorgestel. Hierdie faseverandering hittestoor kan meer hitte stoor as wat water in dieselfde temperatuur band sou kon. Die hitteoordrag tempo na en van baie van die faseveranderingsmateriale (FVM) is egter as gevolg van die lae termiese geleidingskoëfisient, stadig. Hierdie eienskap kan gelukkig verbeter word deur hittepype en hitteoordrag verhogings materiaal soos vinne by te voeg. Hittepype het die inherente eienskap om hitte teen ‘n hoë tempo oor groot afstande, oor te dra, selfs oor ‘n klein temperatuurverskil. In hierdie tesis word ‘n ondersoek rakende ‘n faseverandering storingsisteem wat bestaan uit paraffien was as die FVM en reghoekige hittepype wat te same met met aluminium finne gebruik word om die hitteoordragtempo te verhoog, beskryf. Die stoorontwerp is modulêr en elke module het die kenmerk van hoë hitteoordrag na en van die FVM. Die module het verder ook die eienskap om vining hitte te absorbeer of hitte af te gee. Dit gebeur teen ‘n konstante temperatuur gedurende die faseverandering van die FVM. Presies so ‘n reghoekige module is ontwerp en gebou en onder beheerde hitte absorbering- en hitte verwyderingsiklusse analiseer. Tydens die verhittings eksperiment is ‘n elektriese ketel van gebruik gemaak wat gedien het as die hoë temperatuur bron. Die hitte sink was ‘n hitteruiler wat kraanwater van ‘n konstante hoogte tenk ontvang het. Die resultate van die volledige toets is met die resultate van tydafhanklike numeriese model vergelyk. Hierdie numeriese model bereken teoreties wat die module se storing verrigting onder gegewe toets omstandighede sal wees. Die numeriese model se resultate het goed vergelyk met die resultate van die eksperimente. Die numeriese model van die module is toe aangepas om ‘n sonwaterverwarmer met addisionele stoortenk wat fase verandering materiaal gebruik, te simuleer. Hierdie ontwerp is anders as vorige ontwerpe in die sin dat hoër temperature as wat die warmwatertoestel kan hanteer, in die faseverandering storingstenk, bereik kan word. Die sisteem kan ook as gevolg van die hitteoordrag verhoging materiaal, vinniger verhit of afkoel en teen ‘n vinniger tempo. Die simulasie van die sonwaterverwarmer met FVM word gebruik om die grootte en verrigting van die sisteem te bepaal. Hierdie numeriese model toon aan dat wanneer ‘n addisionele faseverandering storingstelsel in ‘n sonwaterverwarmer toepassing gebruik word, die warm water wat die verbruiker uit die sisteem kan verkry, kan verhoog. Die rede hiervoor is dat meer hitte gestoor kan word, wat beskikbaar gemaak word aan die warm water tenk.
Masoud, Ameli Seied. "Additive layer manufactured sinter-style aluminium/ammonia heat pipes." Thesis, Northumbria University, 2012. http://nrl.northumbria.ac.uk/16880/.
Full textКозак, Дмитро Віталійович. "Теплотехнічні характеристики комбінованого сонячного колектора на основі алюмінієвих канавчатих теплових труб." Thesis, КПІ ім. Ігоря Сікорського, 2018. https://ela.kpi.ua/handle/123456789/25902.
Full textThesis for the Candidate degree in Technical Science on the specialty 05.14.06 «Technical thermophysics and industrial thermal power engineering». – National Technical University of Ukraine "Igor Sikorsky Kyiv Polytechnic Institute", Ministry of Education and Science of Ukraine, Kyiv, 2018. The work is devoted to increasing energy efficiency and simplification of integration of solar systems on the basis of the photovoltaic thermal (PV/T) collector in the facades and roofs of buildings due to use as an element of the absorbing surface of aluminum grooved heat pipes (AGHP). It is established that the efficiency of the operation of the PV/T collector with AGHP in the thermosyphon mode is significantly influenced by the thermal characteristics of the HP, which in turn depends on the following parameters: the diameter of the steam space, the thermophysical properties of the working fluid, the lengths of the heating and condensation zones, and the total length of the AGHP. Increasing the thermal conductivity of AGHP can be achieved by providing a guaranteed amount of coolant to the heating zone and selecting the optimal design parameters of the HP at the appropriate operating modes. A new approach to the implementation of PVT collectors on the basis of AGHPs is proposed. In this case, AGHPs perform a complex role – at the same time it is a highly efficient thermal conductor and a system of cooling solar cells. The design of an aluminum heat pipe with a grooved capillary structure for PVT collectors has been developed. An n-pentane is chosen as the optimum coolant for a two-phase system. The developed samples of heat pipes can provide the operation of the PVT collector in the thermal mode from 0 oC to 120 oC. In this case, the temperature range of its operation is from −40 °C to +230 °C. The analysis of calculations and experimental data showed that the PV/T collector with AGHP allows to increase the efficiency of obtaining electric energy up to 18 % due to the cooling of the PV, while the maximum electric power PV/T collector was 135 W/m2. In addition to electricity, simultaneously, it is possible to get up to 457 W of heat from 1 m2 of heat-absorbing surface, at a temperature of the output coolant 25 oС and a density of solar flux of 900 W/m2. On the basis of theoretical analysis, the most optimal modes of operation of the PV/T collector were identified – the most optimal one is the mode of PV/T collector functioning at values of 30–50 oC of the temperature difference between the absorbent surface and the environment. The new PV/T collector design has a more efficient performance compared to separate thermal solar collectors and photoelectric batteries at low temperatures on an absorbent surface (below 50 oC), and usually at higher solar flux values (over 600 W/m2). The first developed programs and methods of research of PVT collectors in artificial and natural light developed an engineering methodology for calculating the thermal characteristics of PVT collector with AGHPs during their operation in a thermosyphon mode. The recommendations for the production of PVT collectors and their use in solar power systems are given. The results of the work in the future can be used at the enterprises of LLC «Effectprof» (Kyiv), PC Sumy SPO M.V. Frunze (Sumy), PE Scientific-Implementation Firm "Thermal Technologies" (Kiev), which are engaged in the development, manufacture and implementation of heat-exchange equipment and energy-efficient systems. For further implementation, it is necessary to carry out works on designing and manufacturing an industrial design of PVT collector or facade PVT collector and to conduct tests in the field.
Диссертация на соискание ученой степени кандидата технических наук по специальности 05.14.06 «Техническая теплофизика и промышленная теплоэнергетика». – Национальный технический университет Украины «Киевский политехнический институт имени Игоря Сикорского», Министерство образования и науки Украины, Киев, 2018. Работа посвящена повышению энергетической эффективности и упрощению интеграции солнечных систем на основе комбинированных солнечных коллекторов в фасады и крыши зданий за счет использования в качестве элемента теплопоглощающей поверхности алюминиевых канавчатых тепловых труб. Установлено, что на эффективность работы комбинированного солнечного коллектора с алюминиевыми канавчатыми тепловыми трубами в режиме термосифона существенно влияют теплотехнические характеристики тепловых труб, в свою очередь зависят от следующих параметров: диаметр парового пространства, теплофизические свойства рабочей жидкости, длины зон нагрева и конденсации, а также общая длина алюминиевых канавчатых тепловых труб. Повышение теплопередающих способности алюминиевых канавчатых тепловых труб можно достичь благодаря обеспечению подачи гарантированного количества теплоносителя в зону нагрева и выбора оптимальных конструктивных параметров тепловых труб при соответствующих режимах работы. Анализ расчетов и экспериментальных данных показал, что комбинированный солнечный коллектор с алюминиевыми канавчатыми тепловыми трубами позволяет повысить эффективность получения электрической энергии до 18% за счет охлаждения фотоэлектрических преобразователей, при этом максимальная электрическая мощность комбинированного солнечного коллектора составляла 135 Вт/м2. Кроме электроэнергии, одновременно можно получить до 457 Вт тепла с 1 м2 теплопоглощающей поверхности при температуре исходного теплоносителя 25 °С и плотности солнечного потока 900 Вт/м2. На основе теоретического анализа выявлены наиболее оптимальные режимы эксплуатации комбинированного солнечного коллектора – режим функционирования при значениях 30–50 °С температурного перепада между теплопоглощающей поверхностью и окружающей средой. Новая конструкция комбинированного солнечного коллектора имеет более эффективную работу по сравнению с раздельными тепловыми солнечными коллекторами и фотоэлектрическими батареями при низких температурах на теплопоглощающей поверхности (ниже 50 °С) и обычно при более высоких значениях солнечного потока (более 600 Вт/м2).
Wang, Chung-tu, and 王證都. "Fabrication and Experimental Study of the Thin Aluminum Heat Pipe." Thesis, 2014. http://ndltd.ncl.edu.tw/handle/b4tw8p.
Full text國立臺灣科技大學
機械工程系
102
In fulfilling consumer’s requirement on reducing size and weight of mobile devices, especially the notebook, tablet, and cell phone, has generated a urgent demand for manufacturing the light-weight Aluminum heat pipe. Thus, the purpose of this study is to design and manufacture the Al heat pipe that uses pure water as the working medium. Obviously, the major advantages in utilizing Al heat pipe include the lighter weight and cheaper cost compared to the traditional copper heat pipe. However, there are several technical challenges, such as the welding, corrosion, and compatibility issues in using Al as the heat pipe container. Firstly, a thin copper layer is attached closely to the inside wall of Al pipe for preventing the direct contact with water; thus the corrosion and compatibility issues between water and Al can be solved. Also, the YAG laser welding technology is introduced for sealing two ends of Al heat pipe. Furthermore, the systematic procedures for manufacturing and testing this Al heat pipe are proposed and set up successfully. Later, the amount of working medium and the flattened thickness of heat pipe are investigated for identifying the optimum values to yield the highest maximum heat transfer rate. Consequently, it is found that the maximum heat transfer rate enlarges for an increasing working-medium amount under a normal flattened thickness. Nevertheless, a decrease on maximum heat transfer rate is observed for the case of filling too much water when the height of vapor channel inside the heat pipe is less than 0.9 mm. Besides, the results illustrate that heat dissipating capability (30 watts) of the optimized heat pipe is almost identical to that of the traditional copper heat pipe with a 2.2 mm flattened thickness. Therefore, it is suggest that determining the optimized amount of working medium should take into account the cross-sectional geometry of heat pipe. In summary, this study presents a reliable and systematic scheme to fabricating the Al heat pipe.
Chang, Chia-Wei, and 張嘉維. "Design of the cooling module of LEDs based on the aluminum-acetone flat plate heat pipe." Thesis, 2014. http://ndltd.ncl.edu.tw/handle/11726555730910811174.
Full text國立臺南大學
機電系統工程研究所
103
High power light emitting diode array is an important product to promote energy conservation and reduce carbon emissions. But as the LED power increases, the heat flux increases. However, increasing of in the heat flux will lead the LED package to be damaged, and causes the LED brightness reducing. The waste heat generated by high power LED is hardly effectively dissipated, therefore, it results in a serious problem in the luminous efficiency. The most important issue of the LED research is to find a potential design of heat removal and solve the problem of LED over-heating. The purpose of this study is to design the LEDs combined with the cooling module of the aluminum-acetone flat plate heat pipe by experiment for the high efficiency of heat removal. The high power LEDs with heat pipe cooling module, heat sink cooling module and without cooling module are compared. We find that the heat removal efficiency (80.93%) of the aluminum-acetone flat plate heat pipe cooling module is better than the one of heat sink module obviously. The cooling module of the aluminum-acetone flat plate heat pipe has proven to be effective in solving the heat concentration problems associated with the LED chips. In short, the phase change cooling module will apply on the electronic component of high heat concentration for more effective cooling method.
Lin, Bo-Gu, and 林柏谷. "Thermal Performance of Heat Pipes with Alumina Nanofluid." Thesis, 2011. http://ndltd.ncl.edu.tw/handle/28106000520648009283.
Full text國立臺灣師範大學
工業教育學系
99
In this study, a two-step synthesis with a water-soluble dispersant of chitosan was used to produce stable suspensions of Al2O3/water nanofluid as the working fluid of the heat pipe. The thermal conductivity and rheological properties of the alumina/water nanofluids were evaluated. The optimal amount of added dispersant for the Al2O3/water nanofluid was determined. This study presents a discussion of the effects on the thermal performance of the heat pipe of the charged amount of working fluid, the tilt angle and length of the heat pipe, the heating power of the evaporator section, and the weight fraction of nanoparticles. The experimental results show that the optimal concentration of dispersant was 0.2wt.% to follow-up heat pipe thermal performance experiments under the dispersion properties and thermal conductivity simultaneously were considered. In thermal performance experiments, the optimal thermal performance of the heat pipe occurs when the tile angle of the heat pipe and the charged amount of working fluid are 30∘and 20 %~40 %, respectively. The shorter heat pipe is suitable for use in low heating power, and the longer heat pipe is suitable for use in high heating power applications under the same cooling condition. The 30 cm heat pipe can enhance the thermal performance efficiency by 18.72 %~43.78 %, the 45 cm heat pipe by 13.13 %~50.72 %, and the 60 cm heat pipe by 7.44 %~17.67 % when compared with deionized water as the working fluid of the heat pipe. This study confirmed that the Al2O3/water nanofluid has superior heat transport performance in the heat pipe compared with deionized water, and has considerable potential for use in the development of high performance heat pipes.
Yang, Meng-Hsueh, and 楊孟學. "Study on the heat transfer performance of gravity heat pipes with anodized aluminum oxide nano-surface." Thesis, 2017. http://ndltd.ncl.edu.tw/handle/39609746805241192814.
Full text中原大學
機械工程研究所
105
This thesis is conducted with the study on the heat transfer performance of gravity heat pipes with anodized aluminum oxide nano-surface. The main purpose is to experimentally investigate the influences of aluminum oxide nanotube length and diameter on the temperature distribution, thermal resistance, and dryout phenomenon of gravity heat pipes under different thermal powers input. First, the anodic oxidation method is used to generate anodic aluminum nanotubes on the inner wall-surface of the evaporation section of aluminum gravity heat pipes. Then, nano-surfaces with different nanotube lengths and diameters are obtained by controlling the anodic oxidation time and voltage. Further, the shape of those nanotubes are observed by using the FE-SEM. Finally, these gravity heat pipes are placed in a thermal test system so as to measure the temperature, calculate the thermal resistance, and record the dryout phenomenon. The results show that the increase in the anodic oxidation time could increase the length of an anodized aluminum nanotube under a particular thermal power input. Increasing the nanotube length reduces the temperature change between the evaporation section and condensation section and the thermal resistance; moreover, the dryout phenomenon is delayed. In addition, the increase in the anodic oxidation voltage could increase the nanotube diameter. Increasing the nanotube diameter also reduces the temperature change between the evaporation section and condensation section and the thermal resistance; however, the increase in diameter does not seem to affect the dryout phenomenon. In summary, if the anodic oxidation treatment is applied to the inner wall surface of the evaporation section of a gravity heat pipe, the heat transfer performance could be obviously improved. The heat transfer performance of the gravity heat pipe could further be enhanced by increasing the anodic oxidation time and voltage.
Book chapters on the topic "Aluminum heat pipe"
Cepeda-Rizo, Juan, Jeremiah Gayle, and Joshua Ravich. "Phase Change γ-Alumina Aqueous-Based Nanofluid for Improving Heat Pipe Transient Efficiency (The Nano Heat Pipe)." In Thermal and Structural Electronic Packaging Analysis for Space and Extreme Environments, 70–78. Boca Raton: CRC Press, 2021. http://dx.doi.org/10.1201/9781003247005-9.
Full textConference papers on the topic "Aluminum heat pipe"
Lin, Z. R., Z. Y. Lee, L. W. Zhang, S. F. Wang, A. A. Merrikh, and G. Refai-Ahmed. "Heat Transfer Characteristics of Aluminum Plate Pulsating Heat Pipes." In ASME 2011 Pacific Rim Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Systems. ASMEDC, 2011. http://dx.doi.org/10.1115/ipack2011-52018.
Full textCarbajal, Gerardo, G. P. Peterson, and C. B. Sobhan. "Comparison of Performance of Aluminum and Titanium Heat Pipes." In ASME 2007 International Mechanical Engineering Congress and Exposition. ASMEDC, 2007. http://dx.doi.org/10.1115/imece2007-42758.
Full textHong, Su-Hyeon, Seok-Hwan Moon, Kwang-Seong Choi, Jin-Ho Lee, and Hyun-Tak Kim. "A SOLUTION OF ALUMINUM FLAT HEAT PIPE FOR DRY COOLING THE LADAR ARRAY." In International Heat Transfer Conference 16. Connecticut: Begellhouse, 2018. http://dx.doi.org/10.1615/ihtc16.her.022037.
Full textStubblebine, Michael, Ladan Amouzegar, and Ivan Catton. "Passivation and Performance of Inorganic Aqueous Solutions in a Grooved, Aluminum Flat Heat Pipe." In ASME 2013 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2013. http://dx.doi.org/10.1115/imece2013-65641.
Full textCai, Qingjun, Chung-Lung Chen, and Julie F. Asfia. "Heat Transfer Enhancement of Planar Pulsating Heat Pipe Device." In ASME 2006 International Mechanical Engineering Congress and Exposition. ASMEDC, 2006. http://dx.doi.org/10.1115/imece2006-13737.
Full textZimbeck, Walter, Jared Chaney, Patricio Espinoza, Edward Kroliczek, David C. Bugby, and James Yun. "Ceramic Flat Plate Evaporator for Loop Heat Pipe Cooling of Electronics." In ASME 2005 Pacific Rim Technical Conference and Exhibition on Integration and Packaging of MEMS, NEMS, and Electronic Systems collocated with the ASME 2005 Heat Transfer Summer Conference. ASMEDC, 2005. http://dx.doi.org/10.1115/ipack2005-73124.
Full textHoesing, Mitchell P., and Gregory J. Michna. "Integration of a Pulsating Heat Pipe in a Flat Plate Heat Sink." In ASME 2014 12th International Conference on Nanochannels, Microchannels, and Minichannels collocated with the ASME 2014 4th Joint US-European Fluids Engineering Division Summer Meeting. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/icnmm2014-21233.
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