Global ETD Search

61	Inkubátor s regulací teploty a vlhkosti / Incubator with adjustable temperature and humidity Hikaník, Matúš January 2011 (has links) This project deals with comparing types and properties of commercial produced incubators for exotic birds. It searches the best solution from these area. In this project are compars individual components and their choice for realization in this project. Then in this project is solution of regulation temperature and humidity in engineered mechanism and discovered parameters of specifically space. Then is developed solution of thermostat and hydrosatat for this prototype. Temperature is changed by Peltier module, who is involved in correct system. Humidity is regulated by resistor humidifier. Complex system is managed by microcontroler. System communicates with PC via USB interface and Ethernet. Solution of this project is maked functional prototyp.
62	Výpočet teplotního pole přípojnicového mostu / Calculation of temperature field of the busbar bridge Měrka, Ivan January 2016 (has links) This term project’s aim is to theoreticaly analyze thermal phenomena and losses in electrical power devices, describe the design and application of UniGear ZS1 type switchgear, put together a computer simulation model for thermal calculations of current and optimized solution and finally to discuss obtained results and compare them with experimentally acquired values. The main objective of this project is to determine, whether simulation is a viable and reliable enough method, that it could replace the costly real life physical testing. Modelling of the progress of thermal processes in different parts of the examined busbar will be done in computer aided design program Solidworks and its simulation plugin Flow Simulation.
63	Diagnostika a návrh eliminace tepelných mostů budov / Diagnostics and proposal to eliminate thermal bridges buildings Bravenec, David January 2017 (has links) This thesis presents a comparison of building materials for vertical bearing structures of buildings, thermal insulation materials and mutual combination of structural materials and insulators. Furthermore, there are possibilities for solving the most common insulation thermal bridges construction. The paper evaluated the pros and cons of different combinations of building materials. Teplo and Area programs were used for the calculations.
64	The Development of an Accelerated Testing Facility for the Study of Deposits in Land-Based Gas Turbine Engines Jensen, Jared Wilfred 25 June 2004 (has links) (PDF) Turbine engine efficiency modeling depends on many parameters related to fluid dynamics and heat transfer. Many of these parameters change dynamically once the engine enters service and begins to experience surface degradation. This thesis presents a validation of the design and operation of an accelerated testing facility for the study of foreign deposit layers typical to the operation of land-based gas turbines. It also reports on the use of this facility in an effort to characterize the change in thermal resistance on the surface of turbine blades as deposits accumulate. The facility was designed to produce turbine deposits in a 4-hour test that would simulate 10,000 hours of turbine operation. This is accomplished by matching the net foreign particulate throughput of an actual gas turbine. Flow Mach number, temperature and particulate impingement angle are also matched. Validation tests were conducted to model the ingestion of foreign particulate typically found in the urban environment. The majority of this particulate is ceramic in nature and smaller than 10µm in size, but varies in size up to 80µm. Deposits were formed for flow Mach number and temperature of 0.3 and 1150°C respectively, using air plasma sprayed (APS) thermal barrier coat (TBC) material coupons donated from industry. These conditions are typical of a modern, first stage nozzle. Investigations over a range of impingement angles yielded samples with deposit thicknesses from 50 to 200µm in 4-hour, accelerated-service simulations. Above a threshold temperature, deposit thickness was dependent primarily upon particle concentration. Test validation was achieved using direct comparison with deposits from service hardware. Deposit characteristics affecting blade heat transfer via convection and conduction were assessed. Surface topography analysis indicated that the surface structure of the generated deposits were similar to those found on actual turbine blades. Scanning electron microscope (SEM) and x-ray spectroscopy analyses indicated that the deposit microstructures and chemical compositions were comparable to turbine blade deposit samples obtained from industry. A roadmap for the development of a theoretical model of thermal resistance using the SEM scan is presented. Thermal resistance experiments conducted with deposit samples indicate that a general decrease in thermal resistance occurs as the samples are exposed to operating conditions in the accelerated testing facility. This is likely due to sintering effects within the TBC dominating any thermal resistance increase arising from deposition. Recommendations for future research into the interaction between TBC sintering and deposit evolution are presented. gas turbine engine degradation power generation heat transfer accelerated deposit facility thermal resistance mechanical engineering turbomachinery Brigham Young University BYU Department of Energy DOE Mechanical Engineering
65	Thermal Analysis of a Sea Wave Generator Quijada, Ezequiel January 2017 (has links) Wave power has been increasing the interest of many researchers looking for alternative sustainable energy sources since the reserves have proved to be capable of satisfying a considerable percentage of the world´s energy demands. This option has not been adopted as a sustainable source since there are some challenges in the process of designing a low cost device that converts the kinetic energy of the waves into electric energy and that could still be efficient enough to be competitive against other options. A new proposal from Anders Hagnestål looks like a very promising way of moving forward in this field. The structure of this newly proposed generator includes neodymium magnets that at temperatures over 60°C might suffer irreversible demagnetization, compromising the normal functioning of the machine. Because of the electrical losses in iron components, overheating is a possibility that must be studied. The aim of this study is to find the temperature distribution of the components that are subject to changing magnetic fields (where the losses will occur). This will be done for a variety of cases regarding environmental and working conditions with the purpose of determining if the generator will need a cooling technique to avoid damage to the magnets. The studied structure consists of a stator and a translator conformed by iron, FR4, glass fiber and, of course, the magnets. The task at hand was carried out first through a one-dimensional analytical model, then through a two-dimensional analytical model and finally by means of simulations on Comsol Multiphysics (Computer-Aided-Engineering software). All of the aforementioned methods implicate assumptions that deviate from reality, but are still useful for the task at hand. Results from the 1D calculation turned out to be unreliable due to the numerous approximations but helped to prove and understand the effect of each of the environmental conditions on the temperature distribution. On the other hand, the 2D calculations and the simulations had a very good agreement which provides some reliability. Furthermore, said results showed that the components might even reach temperatures as high as 380°C under certain conditions. As this number is clearly over the safe limit of the magnets, it was concluded that cooling techniques are needed to ensure the safety of the generator. After some discussion with Hagnestål, cooling methods were proposed. In addition to this, the seemingly most appropriate option was pointed out with the intention of achieving a low-enough temperature and keeping the costs as low as possible. This alternative was a combination of modifying geometric parameters (which would ultimately reduce heat generation) and inducing a low velocity air flow. / Vågkraft är en hittills outnyttjad förnybar energikälla som i framtiden kan tillgodose i storleksordningen 10 % av världens energibehov, om de tekniska utmaningarna kan lösas så att vågkraft kan levereras till konkurrenskraftiga priser. Därmed finns också ett starkt intresse från både akademi och näringsliv att lösa dessa utmaningar. Anders Hagnestål håller på att utveckla en ny linjär generatortyp som enligt beräkningar slår alla befintliga lösningar för effektomvandling för vågkraft med bred marginal. Maskinen har dock komplex geometri, och det är svårt att beräkna dess prestanda. Maskinen innehåller neodymmagneter, vilka kan avmagnetiseras om de blir för varma där 60°C kan ses som en gräns då magneterna börjar påverkas. Om magneterna avmagnetiseras blir maskinen svagare. Eftersom magneterna upphettas av virvelströmmar i magneterna och förluster i omgivande elektroplåt, är det av intresse att göra en termisk analys av maskinen vilket är syftet med detta examensarbete. Målet är att beräkna temperaturutbredningen i maskinens olika delar vid olika driftsfall, och se om man behöver tillföra extern kylning av maskinen för att skydda magneterna. Maskinen består av en translator som omsluter den inre statorn där magneterna är lokaliserade, vilka är byggda av fiberkompositer, elektroplåt, rostfritt stål och neodymmagneter. Beräkningar gjordes först med en endimensionell analytisk modell, därefter med en tvådimensionell analytisk modell och slutligen med numeriska beräkningar i 2D med det kommersiella finita elementmetodberäkningsprogrammet Comsol Multiphysics. Samtliga dessa modeller har avvikelser från det verkliga fallet, men är ändå användbara och ger en fingervisning om hur den termiska situationen för maskinen kan se ut. 1D-beräkningarna visade sig innehålla lite för grova approximationer för att ge pålitliga resultat, men gav en del intuitiv insikt om problemet. Den analytiska 2D-beräkningen stämde bra överens med Comsol-beräkningen, vilket indikerar att beräkningarna är korrekta. Resultaten visade på mycket höga temperaturer i vissa driftsfall utan kylsystem, 380 °C, vilket är en indikator på att antingen någon form av kylning förmodligen behövs, i.a.f. i en del driftsfall, eller att värmeförlusterna i den delen av generatorn behöver minskas genom t.ex. att pollängden ökas. En kombination av luftflöden med låg hastighet och förändrad geometri har föreslagits i examensarbetet för att minska temperaturen. sea wave power generator magnet overheating demagnetization heat transfer conjugate heat transfer thermal resistance Comsol Multiphysics cooling technique Elektroteknik och elektronik
66	Packaging of Enhancement-Mode Gallium Nitride High-Electron-Mobility Transistors for High Power Density Applications Lu, Shengchang 27 June 2022 (has links) Gallium nitride (GaN) high-electron-mobility transistors (HEMTs) are favored for their smaller specific on-resistance, lower switching losses, and higher theoretical temperature limits as compared to traditional silicon (Si) power switches. They have the potential to dramatically increase the power density and efficiency of power electronics systems by replacing traditional Si-based switches. However, GaN HEMTs have a faster switching speed compared to their Si-based counterparts. Minimizing the parasitic loop inductances of the GaN HEMT package is crucial for reducing electromagnetic interference (EMI) noise and voltage spikes. Another concern with GaN HEMTs comes from their lower thermal conductivity and smaller die size. The HEMTs generally have a higher heat flux density, and accordingly, demand better heat dissipation. Thus, innovations are needed for making GaN HEMT packages with low parasitic inductances and higher thermal performances to further their applications in high-frequency, high-power-density converters. To reduce loop inductance, other researchers have embedded GaN HEMTs in a printed circuit board (PCB) and used plated vias for interconnections and heat dissipation. However, this approach requires more complex manufacturing steps and has lower thermal performance. This dissertation introduces different embedded packaging techniques for 650V, 150A GaN HEMTs; this method involves interconnecting the bare chips between direct-bonded copper (DBC) and a PCB or between two DBCs, as discussed in Chapter 2. Vertical interconnections by gold pins and silver rods are introduced and implemented in embedded packages to limit the parasitic loop inductance within 1.5 nH and parasitic resistances within 1.5 mΩ. The thermal performance of the embedded GaN HEMT packages is experimentally verified in Chapter 2; then, the junction-to-case thermal resistance (RthJC) measurement is discussed in Chapter 3. The common temperature-sensitive electrical parameters (TSEPs) of a GaN HEMT for junction temperature measurement lack sufficient sensitivity or stability due to the electron-trapping effect. The non-uniform distribution of the case temperature and a large temperature gradient between the case and heatsink also make it difficult to accurately measure the case temperature. In Chapter 3, gate-to-gate resistance (Rg2g) is selected as the TSEP for junction temperature measurement. The stacked thermal interface material (TIM) technique was used to reduce errors in case temperature measurement. This technique was implemented in a custom GaN HEMT package and in embedded GaN HEMT packages for measuring junction-to-case thermal resistance. The discrepancy between measurement and simulation is less than 20%, and the junction-to-case thermal resistance for embedded packages is within 0.1 °C/W. Chapter 4 evaluates the reliability of the GaN HEMT embedded packages developed in Chapter 2 by utilizing a power cycling test. Monitoring the junction temperature of the embedded packages online is challenging during the power cycling test. Other approaches have used the on-resistance as the TSEP in order to monitor junction temperature for GaN HEMTs but this is not accurate due to electron trapping. As discussed in Chapter 3, Rg2g is chosen as the TSEP to monitor the junction temperature without worrying about the influence of electron trapping, and this approach cycles the embedded packages at 75 A from 25°C to 125°C. The packages can endure 23,000 power cycles before failure. This work is the first to develop, fabricate, and characterize embedded packages for 650V, 150A GaN HEMT bare chips. These embedded packages with high-power-rated GaN HEMT bare dice provide an opportunity to reduce the number of paralleled power switches, reduce the system's cooling size, and increase the system's power density. In addition, this work is the first to develop the junction-to-case thermal resistance measurement technique by gate-to-gate electrical resistance and stacked-TIM for GaN HEMT packages. The technique helps enable solid thermal design for power electronics systems. / Doctor of Philosophy / Power switches are everywhere in our daily life. They are the fundamental elements in power converters for converting power to electric vehicles. As global power demand for these applications continues to increase, high levels of both efficiency and power density are crucial for power switches. However, traditional silicon-based switches are already very mature, and their properties are very close to their theoretical limits. For further improvement, researchers have tried to replace traditional Si switches with wide-bandgap switches, which have much higher theoretical limits. Gallium nitride high-electron-mobility transistors (GaN HEMTs) are one of the candidates. However, packaging these switches (GaN HEMTs) is challenging due to their initial properties. They naturally switch very quickly and have smaller sizes compared to traditional Si-based switches. The fast switching speed brings high dv/dt and di/dt during the switching period. It causes voltage spikes and electromagnetic interference (EMI) issues. And the smaller size contributes to higher heat flux density, thus requiring more efficient heat dissipation. To solve the challenge of packaging GaN HEMTs, this dissertation has developed embedded packaging techniques to achieve quiet switching and good heat dissipation. These packaging techniques enable GaN HEMTs' advantages and increase the power density and efficiency of power electronics systems. To experimentally verify the thermal performance of the embedded packages developed a junction-to-case thermal resistance measurement technique was introduced. The thermal resistance of a custom GaN HEMT package was measured, as were those of the embedded packages CPES also developed. The simulation results and the experimental results are close to each other. Finally, to further evaluate whether or not the newly developed embedded packages are reliable, power cycling tests were carried out at I = 75 A. The packages survived over 23,000 cycles before failure. Power electronics packaging parasitic inductance junction-to-case thermal resistance high-temperature encapsulation materials reliability
67	Оптимизация толщины изоляции теплопровода при канальной прокладке : магистерская диссертация / Optimization of insulation thickness of the heat pipe laid in the channel Осипов, Р. В., Osipov, R. V. January 2019 (has links) Диссертация посвящена исследованию проблемы нерационального использования теплоизоляционного слоя при канальной прокладке трубопроводов в непроходных каналах. Определены все термические сопротивления тепловому потоку различных составляющих теплотрассы. Спрогнозированна примерная окупаемость теплоизолируещих слоев различной толщины. Выявлена наиболее оптимальная толщина теплоизолируещего слоя. Для более точного определения теплопотерь трубопроводов в непроходном канале, в программном коплексе ANSYS® построена модель поперечного сечения теплотрассы. Выявлен режим свободной конвекции внутри канала. Смоделированы поля распределения скорости и температуры для сеток различного качества при различных моделях турбулентности. / The thesis is devoted to the study of the problem of the irrational use of the heat-insulating layer in the channel laying of pipelines in impassable channels. All thermal resistance to the heat flux of various components of the heating main are determined. The estimated payback of heat-insulating layers of various thicknesses is predicted. The most optimal thickness of the insulating layer was revealed. To more accurately determine the heat loss of pipelines in a non-passage channel, a cross-sectional model of a heating main has been built in ANSYS®. The mode of free convection inside the channel is revealed. The velocity and temperature distribution fields are simulated for grids of various quality with various turbulence models. ОКУПАЕМОСТЬ ANSYS MASTER'S THESIS PIPE INSULATION THERMAL RESISTANCE PAYBACK NUMERICAL SIMULATION FREE CONVECTION IN THE CHANNEL ANSYS
68	Surface Interactions with Hierarchical Nanostructures: From Gecko Adhesion to Thermal Behavior Klittich, Mena R. January 2017 (has links) No description available. Polymers Zoology Physics Nanoscience Experiments Condensation Adhesion gecko carbon nanotubes thermal conductivity roughness frost softness surface energy hierarchical structure thermal interface material thermal resistance surface foam superhydrophobic
69	Développement de diodes laser émettant à 975nm de très forte puissance, rendement à la prise élevé et stabilisées en longueur d’onde pour pompage de fibres dopées et réalisation de lasers à fibre / Development of high-power laser diodes emitting at 975nm with enhanced wall-plug efficiency and wavelength stabilization for optical pumping of doped fibers and realization of fiber lasers Mostallino, Roberto 05 September 2018 (has links) Cette thèse CIFRE adresse le développement de diodes laser, émettant à 975nm, de très forte puissance, rendement à la prise élevé, et stabilisées en longueur d’onde pour pompage de fibres dopées Er/Yb et réalisation de lasers à fibre. La thèse a été développée dans le cadre d’un partenariat étroit entre le Laboratoire IMS, le GIE III-V Lab, principal fondeur français de composants à semiconducteurs III-V pour des applications électroniques et photoniques, et THALES Research & Technology à Palaiseau en région parisienne. Un travail en profondeur de caractérisation et d’analyse a porté sur les aspects thermiques qui contribuent, en particulier,à limiter les niveaux de puissance optique de sortie. Dans ce cadre, nous avons réalisé un ensemble de caractérisations complémentaires au GIE III-V lab et à l’IMS nous permettant d’envisager des solutions correctives d’optimisation technologique portant en particulier sur la profondeur de gravure définissant la largeur de la zone d’émission et la nature du substrat dissipateur. Ces solutions ont été proposées à partir de modélisations physiques mises en oeuvre avec un simulateur dédié, propriété de III-V Lab et de simulations par éléments finis thermiques et thermomécaniques (approche multiphysique) de la structure microassemblée définitive. Ces travaux se sont prolongés par la fabrication et la caractérisation électro-optique et thermique de plusieurs structures verticales : LOC (Large Optical Cavity), SLOC (Super Large OpticalCavity) et AOC (Asymetrical Optical Cavity). Les diodes laser de type LOC et SLOC sont stabilisées en longueur d’onde en intégrant un réseau de Bragg (DFB). Une puissance optique de 8W avec une efficacité de 60% a été obtenue ; ce qui permet de situer ces travaux à l’état de l’art international notamment vis-à-vis de ceux publiés par l’Institut Ferdinand-Braun.L’originalité des travaux menés dans cette thèse nous a permis d’avoir accès à une bourse du Cluster européen « Laserlab » (The Integrated Initiative of European Laser Research Infrastructures), pour conduire des campagnes d’expérimentation à l’Institut Max Born à Berlin dans le groupe du Dr J.W. Tomm. Les travaux ont porté sur la caractérisation thermique de ces diodes laser de forte puissance émettant à 975nm, à double hétérostructure symétrique et asymétrique (SLOC et AOC), en utilisant des techniques complémentaires (microphotoluminescence,photoluminescence résolue en temps, spectroscopie de photocourant et mesures L-I pulsées) et permettant d’évaluer le type de contraintes résiduelles apportées par les étapes de report de la diode Laser ainsi que la cinétique de dégradation catastrophique de type COD. / This PhD addresses the development of high-power laser diodes emitting at 975nm withhigh efficiency and wavelength stabilized using a Bragg grating. This thesis was conducted in the framework of a close partnership between IMS Laboratory, the GIE III-V lab, who is themain French founder of III-V semiconductor devices for electronic and photonic applications,and THALES Research & Technology in Palaiseau. An in-depth characterization and analysiswork has addressed thermal aspects that contribute, in particular, to limit the optical outputpower of a laser diode. In such a context, we have carried out a set of complementary characterizations both at III-V lab and IMS allowing us to provide some corrective solutionsfor technological optimization concerning the etching depth of the grooves that defines the emitting stripe of the laser diode and the nature of the submount acting as a thermocompensator.These solutions have been proposed from optical modelling implemented with a dedicated simulator, property of III-V lab, and thermal and thermomechanical (multiphysics approach) finite element simulations of the overall microassembled structure. All this work has resulted in the fabrication as well as electro-optical and thermal characterizations of three vertical structures namely LOC (Large Optical Cavity), SLOC (Super Large Optical Cavity)and AOC (Asymmetrical Optical Cavity). The LOC and SLOC vertical structures have been processed with a Fabry-Perot cavity and also including a Bragg grating (DFB architecture) while the AOC one was only fabricated with a Fabry-Perot cavity. State-of-the-art results aredemonstrated since in particular an optical power of 8W with an efficiency of 60% has been obtained that can be compared to those recently published by the Ferdinand-Braun Institute.The originality of the work carried out in this PhD has allowed us to receive a grant from the European Laserlab Cluster (The Integrated Initiative of the European Laser Research Infrastructures), to conduct dedicated experiments at the Max-Born Institute (Berlin) in thegroup of Dr. J.W. Tomm. The work aimed to characterize mechanical strain of the laser diode induced by the soldering process. Two vertical structures (SLOC and AOC) were investigated using complementary techniques (microphotoluminescence, time-resolved photoluminescence,photocurrent spectroscopy and pulsed L-I measurements), allowing to quantify the level of residual stress provided by the laser diode mounting process as well as the kinetics of the catastrophic degradation process (COD). Optoélectronique Diode laser Caractérisation électro-optique DFB 975nm Simulation par éléments finis Thermique Thermomécanique Résistance thermique Micro-photoluminescence Optoelectronics Laser diode Electro-optical characterization DFB 975nm Finite element simulation Thermal Thermomechanical Thermal resistance Microphotoluminescence
70	Avaliação da produção e viabilidade de esporos de Bacillus atrophaeus ATCC 9372 utilizando resíduos do processamento de suco de laranja / Evaluation of production and viability of Bacillus atrophaeus ATCC 9372 spores using orange juice processing waste Lenhardt, Elizandra Hertel 02 May 2016 (has links) O Brasil é um dos maiores produtores mundiais de suco de laranja, da mesma forma que a produção é elevada, a geração de resíduos também é significativa. Sabe-se que estes resíduos, os quais incluem sementes, cascas e restos de polpa são ricos em nutrientes que poderiam ser utilizados como substrato por micro-organismos, seja para o crescimento ou para a obtenção de subprodutos. Esporos de Bacillus atrophaeus ATCC 9372 são utilizados como indicadores biológicos, IBs, em processos térmicos por formarem esporos termorresistentes. O objetivo deste trabalho foi avaliar o uso de resíduos do processamento de suco de laranja como um meio de cultura alternativo para obtenção de esporos de B. atrophaeus, para serem aplicados em processos industriais. Ao bagaço de laranja (de 1,0 g a 20,0 g), obtido por processamento em centrífuga de frutas, foram adicionados 100 mL de água, e incubados a 150 rpm / 37 ºC por até 6 dias. Evidenciada a viabilidade de crescimento celular (µmáx = 0,0238 h-1 e Px = 0,0787 g/L.h, para 5,0 g de bagaço) procedeu-se ao estudo de planejamento experimental fatorial 22 em formato estrela com 6 pontos centrais, considerando a concentração de bagaço e o volume de meio. Foram determinados os valores de pH, de biomassa, de esporos viáveis e a resistência térmica dos mesmos a 102 ºC. Observou-se que houve aumento nos valores de pH após o cultivo e que as maiores concentrações de esporos foram de 1,73 x 109 esporos /mL e 5,75 x 109 esporos /mL após 3 e 6 dias de cultivo e os tempos de redução decimal determinados variaram de D102C = 0,92 min a D102C = 2,71 min e de D102C = 1,34 min a D102C = 3,98 min após 3 e 6 dias de cultivo, respectivamente. Com base no planejamento proposto e a análise de regressão, o desenvolvimento de esporos em bagaço segue a relação: Esporos = {-1,15 + 0,0303* [bagaço (g)] - 0,00611* [volume (mL)] + 0,611* [tempo (dias)]}, p=0,000, R2 =0,452, sendo o tempo (p=0,000) o fator de maior influência na formação de esporos. Os meios preparados com bagaço de laranja apresentaram-se viáveis para a produção de esporos de B. atrophaeus termorresistentes, produto de interesse farmacêutico e industrial, agregando valor ao resíduo que seria descartado. / Brazil is one of the world´s largest producers of oranges juice, in the same way that the production is high the amount of generated waste is also significant. It is well known that these residues, which include seeds, peel and pulp, are rich in nutrients that could be used as substrate by microorganisms whether for growth or for obtaining by-products. Bacillus atrophaeus ATCC 9372 spores are used as biological indicators, BIs, in thermal processes due to their ability to form heat-resistant spores. This study aimed to evaluate the use of orange juice processing waste as an alternative culture media to obtain B. atrophaeus spores, to be applied in industrial processes. To orange\'s bagasse (from 1.0 g to 20.0 g), obtained by processing in a fruit\'s centrifuge, 100 mL of water was added, and sterilized at 121 ºC. An aliquot of 0.1g/L of Bacillus atrophaeus spores was inoculated to bagasses\'s media and incubated at 150 rpm / 37 ºC up to 6 days. As cells (µmáx = 0.0238 h-1 and Px = 0.0787 g/L.h, for 5.0 g of bagasse) were obtained, a factorial experimental design 22, with star-shaped model and 6 central points, was performed considering the bagasse concentration and the media volume used. Values of pH, biomass, viable spores and their thermal resistance at 102 ºC were determined. It was observed that pH increased after cultivation and major values of spore concentration achieved were 1.73 x 109 spores /mL and 5.75 x 109 spores /mL after 3 and 6 days, respectively. Decimal reduction times determined ranged from D102C = 0.92 min to D102C = 2.71 min and from D102C = 1.34 min to D102C = 3.98 min after 3 and 6 days of incubation, correspondingly. The regression analysis showed that the development of spores in bagasse can be defined by the equation: Spores = , p=0.000, R2 =0.452 and time has a positive influence in the spore formation. Results demonstrated media prepared with oranges\' bagasse were capable to grow and to develop B. atrophaeus heat-resistant spores, being an alternative to add value to a waste that would be discarded, generating a product of great importance in the pharmaceutical field. Agricultural residues Applied microbiology Bacillus atrophaeus spores Biological indicator D value Esporos de Bacillus atrophaeus Indicador biológico Microbiologia aplicada Processamento de laranja Processing of orange Resíduos agroindustriais Resistência térmica Thermal resistance Valor D

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