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Thermal properties of polymer derived Si-O-C-N ceramicsSanthosh, Balanand 23 June 2020 (has links)
The main objective of the thesis is to study the thermal properties of Si-based polymer derived ceramics (PDCs) at elevated temperatures and to classify the main factors affecting the thermal transport through these ceramics. The polymer derived ceramics with the chemistry Si- O-C-N were prepared starting from commercial polycarbosilane, polysiloxane, and polysilazane precursors. These precursors are cross-linked at room temperature to obtain the preceramic, followed by controlled pyrolysis (at different temperatures ranging from 1200 oC to 1800 oC in argon, nitrogen or carbon-di-oxide atmospheres), to get the final ceramic.
The first part of the thesis discusses on development and studies of dense polymer derived thin disks having a basic chemistry, Si-C, Si-O- C, and, Si-C-N-O, developed via a casting technique followed by specific pyrolysis cycles. Having a thickness in the range of 100 μm- 300 μm, these ceramic disks were studied to be nanocrystalline/amorphous at least up to a temperature of 1400 oC and were found to have a significant amount of Cfree phase existing in them along with the intended chemistry. The high-temperature thermal properties were primarily investigated on ceramics prepared at a pyrolysis temperature of 1200 oC (ceramic still in nanocrystalline/amorphous glassy phase). The disks were found to have very low expansion coefficients (CTE) measured up to ~900 oC and the thermal diffusivity (k) and thermal conductivity (l) of these disks were also measured. An attempt to understand the influence of the different phases in a SiOC ceramic (mainly the Cfree phase, studied by enriching the carbon percentages using DVB) in determining the final thermal properties was also conducted. The influence of carbon enrichment on the mechanical properties of these disks is also studied as a sub-part of this work.
The second part of the work deals with testing the possibility to use these ceramics for high-temperature insulation applications. ‘Reticulated’ ceramic foams of relatively same chemistries as that of the disks were prepared by a template replica approach, using polyurethane (PU) foams (more open-celled to more closed-celled types of PU foams were used in the study) as the template. Porous structures having densities ranging from as low as 0.02 g.cm-3 to 0.56 g.cm-3 and with a porosity ~ 80 % to ~99% were prepared and tested. The developed foams showed excellent thermal stability up to a temperature of 1400 oC and possessed very low thermal expansion. The thermal conductivity measured on them at RT gave values in the range 0.03 W.m-1.K-1- 0.25 W.m-1.K-1. A Gibson-Ashby modeling approach to explain the thermal conductivity of the porous ceramics was also attempted. The developed foams were also found to be mechanically rigid.
In a nutshell, the thesis work studies the thermal properties of Si-O-C- N ceramics in detail and probes into the possibility to develop these class of Si-O-C-N ceramics into promising high-temperature insulation material.
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Mechanical and thermal properties of lightweight concrete produced with polyester-coated pumice aggregateBideci, A., Bideci, O.S., Ashour, Ashraf 17 June 2023 (has links)
Yes / With the technological advances in the field of building materials, there has been an increasing focus on the research of lightweight concrete made with coated aggregates for improving the durability of concrete. In this study, pumice aggregates were coated with cast-based polyester to obtain polymer-coated pumice aggregates (PCPA). Lightweight concretes were produced with different cement dosages (200, 250 and 300) and PCPAs at different ratios (0%, 50% and 100%). Physical properties, mechanical strength, thermal properties and internal structure analysis (SEM-EDS) of the produced concrete samples were performed. According to the RILEM functional classification of lightweight concrete, the test results showed that REF D300 and REF D250 dosage series are in the semi-load-bearing lightweight concrete class, and the other all series are in the insulation concrete class, and the produced concretes can be classified as lightweight insulation materials. It can also be used in non-load-bearing walls or as an alternative lightweight insulation material. / The first author wish to thank the support of Scientific and Technical Research Council (TUBITAK) BIDEB-2219 Postdoctoral Research (Project Number: 1059B192100644) and the second author also thank to the Düzce University.
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Carbon nanotube sheet for structural health monitoring and thermal conductivity in laminated compositesKhwaja, Moinuddin 04 November 2019 (has links)
No description available.
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THERMAL METROLOGY AND CHARACTERIZATION OF HIGH THERMAL CONDUCTIVITY POLYMER FIBERS AND FABRICSAaditya Candadai (10277555) 16 March 2021 (has links)
<p>Recent
technological advances in the field of electronics and the accompanying trend
of device miniaturization with enhanced functionality has led to growing
interest in new methods of electronic device integration. As a result,
flexible, wearable, and portable electronic devices have emerged as a way of
providing a multifunctional infrastructure to facilitate various consumer
needs, creating new challenges for materials development. Polymers possess a
unique combination of desirable properties such as mechanical compliance,
durability, low density and chemical stability which makes them ideally
suitable as substrate materials to cater to such diverse applications. However,
the low thermal conductivity of polymers hinders their heat spreading
capability in thermal management applications for flexible and wearable
devices. In recent years, there has been a growing interest in ultra-high
molecular weight polyethylene (UHMW-PE) materials with aligned polymer chains
due to their remarkably high thermal conductivity that is similar to some
metals. These are commercially manufactured in large volumes as fibers using
gel-spinning and ultra-drawing processes that impart a high degree of
crystallinity and orientation to the polymer chains. As a result, these
materials develop exceptionally high mechanical strength, elastic modulus, and
thermal conductivity compared to conventional polymers. Therefore, UHMW-PE
materials have found applications in commercial products like motorcycle gear
and ballistic vests, but have not been commercially deployed for heat spreading
and thermal management applications. While there has been much fundamental work
on the development of high thermal conductivity fibers, effective translation
of the high conductivity from individual fibers to macroscale (wearable)
flexible fabrics has not been previously explored. The objective of this thesis
is to obtain a fundamental understanding of the thermal transport properties of
fabric materials constructed from the high conductivity polymer fibers, and assess
their applicability for potential heat spreading applications. </p>
<p>In the present
work, commercially available high thermal conductivity fibers made of UHMW-PE
are utilized to fabricate plain-weave fabrics prototypes, and the thermal
properties of individual fibers, yarns, and woven fabrics are measured using a
novel in-plane thermal measurement method. The characterization technique
leverages infrared (IR) microscopy for a non-contact temperature sensing and is
generally scalable for thermal characterization of the in-plane
thermal-conductivity of materials across different length scales. Effective
thermal conductivities on the order of ~10 Wm<sup>-1</sup>K<sup>-1</sup> are
achieved along the in-plane dominant heat transport direction of the woven
fabric, which is exceptionally high (~2-3 orders of magnitude) compared to
conventional clothing and textile-based materials. The thermal conductivity and
mechanical flexibility of the UHMW-PE fabrics are benchmarked with respect to
conventional materials and the effect of bend-stressing and thermal annealing
of the fabrics is characterization using the developed metrology. </p>
<p>Additionally, a
laser-based IR thermal metrology technique leveraging both non-contact heating
and temperature sensing is conceptualized and validated using a numerical
thermal modeling approach. The proposed technique provides an approach to
estimate the in-plane heat spreading properties of anisotropic materials with
direction-depended thermal properties based on quantifying the surface
temperature map of a sample subjected to periodic heating. Numerical
simulations are leveraged to demonstrate the applicability of this method to
enable measurement of a wide range of thermal properties indicating great
potential to develop this further as a standardized robust method for in-plane
anisotropic thermal characterization of materials such as fabrics and films.</p>
<p>This work sheds
light on the high thermal conductivity of UHMW-PE materials that can be
achieved using a scalable manufacturing process and describes the thermal metrology
approaches to enable their characterization, thereby providing a foundation for
the conceptualization and design of flexible substrate based thermal solutions
in future wearable/flexible electronic devices.</p>
<p> </p>
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Investigation of the Effect of Particle Size and Particle Loading on Thermal Conductivity and Dielectric Strength of Thermoset PolymersWarner, Nathaniel A. 05 1900 (has links)
Semiconductor die attach materials for high voltage, high reliability analog devices require high thermal conductivity and retention of dielectric strength. A comparative study of effective thermal conductivity and dielectric strength of selected thermoset/ceramic composites was conducted to determine the effect of ceramic particle size and ceramic particle loading on thermoset polymers. The polymer chosen for this study is bismaleimide, a common aerospace material chosen for its strength and thermal stability. The reinforcing material chosen for this study is a ceramic, hexagonal boron nitride. Thermal conductivity and dielectric breakdown strength are measured in low and high concentrations of hexagonal boron nitride. Adhesive fracture toughness of the composite is evaluated on copper to determine the composite’s adhesive qualities. SEM imaging of composite cross-sections is used to visualize particle orientation within the matrix. Micro-indentation is used to measure mechanical properties of the composites which display increased mechanical performance in loading beyond the percolation threshold of the material. Thermal conductivity of the base polymer increases by a factor of 50 in 80%wt loading of 50µm hBN accompanied by a 10% increase in composite dielectric strength. A relationship between particle size and effective thermal conductivity is established through comparison of experimental data with an empirical model of effective thermal conductivity of composite materials.
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Methylol-Functional Benzoxazines: Novel Precursors for Phenolic Thermoset Polymers and Nanocomposite ApplicationsBaqar, Mohamed Saad 23 August 2013 (has links)
No description available.
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In-Pile Thermal Conductivity Measurement Methods for Nuclear FuelsFox, Brandon S. 01 May 2010 (has links)
Measuring nuclear fuel thermal conductivity in-pile can provide much needed data for understanding fuel performance during irradiation and yield thermophysical property data needed for simulation codes and fuel databases. The objective of this research is to develop and compare two in-pile thermal conductivity methods in a laboratory setting using surrogate fuel materials.
A steady-state radial heat flow method was investigated to understand its viability as an in-pile steady-state thermal conductivity technique. By using Joule heating to simulate volumetric heat generation within a surrogate fuel rod, thermal conductivity was measured with two thermocouples at different radial positions within the rod. Examinations were completed on two batches of surrogate materials over the temperature range of 500 to 700 °C. The selected surrogate rod was fabricated from the only material identified to possess the required thermal conductivity and electrical resistivity required for the selected laboratory approach. Evaluations estimated a measurement uncertainty of 12% and values were within 33% of values obtained using laboratory material property measurement systems for this surrogate material. Results indicate that the selected surrogate rod material limited the ability to assess this approach at higher temperatures in a laboratory setting.
A transient needle probe method adapted from American Standard Test Method standards was also used to measure temperature-dependent thermal conductivity of surrogate fuel rod materials for temperatures ranging from room temperature to 400 °C. The needle probe has a heating element and a temperature sensor contained in a metal sheath, and it is inserted into the surrogate fuel rod whose thermal conductivity is to be measured. The thermal conductivity is calculated from the power applied to the heating element, and the temperature rise detected in the sample. Needle probes were designed and fabricated using materials recommended for in-pile application. Scoping room-temperature values obtained using the needle probe method were within acceptable accuracies defined by the ASTM needle probe reference standard. Temperature-dependent values were within 2% of values for the well-characterized ASTM recommended reference material, fused silica. A measurement uncertainty under 6% was calculated for the needle probe method.
As a result of this study, the needle probe method was selected for additional testing at the Idaho National Laboratory for anticipated testing in Materials Test Reactors. This would result in the first-ever transient in-pile thermal conductivity sensor.
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Tepelná vodivost u nestandardních materiálů pro TZB / The thermal conductivity of non-standard materials for HVACBěťák, Karel January 2019 (has links)
The thesis is focused on the determination of the thermal conductivity coefficient on the group of thermoplastics used for 3D printing (PLA, ABS, PETG). The thesis describes the materials used for 3D printing and the design of air conditioning for the grocery store. A stationary method was used for the solution. The heat flux passing through the sample was measured and the thermal conductivity coefficient was calculated. By the chosen method, we determined the coefficient is = 0,11-0,13 W/(m·K). Comparison with the available results of other methods and authors has shown that the resulting coefficient is lower. Based on the data, it is possible to compare the thermal properties of 3D printing materials.
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Multiscale modeling of thermal conductivity of polycrystalline graphene sheetsMortazavi, Bohayra, Pötschke, Markus, Cuniberti, Gianaurelio 02 December 2019 (has links)
We developed a multiscale approach to explore the effective thermal conductivity of polycrystalline graphene sheets. By performing equilibrium molecular dynamics (EMD) simulations, the grain size effect on the thermal conductivity of ultra-fine grained polycrystalline graphene sheets is investigated. Our results reveal that the ultra-fine grained graphene structures have thermal conductivity one order of magnitude smaller than that of pristine graphene. Based on the information provided by the EMD simulations, we constructed finite element models of polycrystalline graphene sheets to probe the thermal conductivity of samples with larger grain sizes. Using the developed multiscale approach, we also investigated the effects of grain size distribution and thermal conductivity of grains on the effective thermal conductivity of polycrystalline graphene. The proposed multiscale approach on the basis of molecular dynamics and finite element methods could be used to evaluate the effective thermal conductivity of polycrystalline graphene and other 2D structures.
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Estimating Thermal Conductivity and Volumetric Specific Heat of a Functionally Graded Material using Photothermal RadiometryKoppanooru, Sampat Kumar Reddy 12 1900 (has links)
Functionally graded materials (FGMs) are inhomogeneous materials in which the material properties vary with respect to space. Research has been done by scientific community in developing techniques like photothermal radiometry (PTR) to measure the thermal conductivity and volumetric heat capacity of FGMs. One of the problems involved in the technique is to solve the inverse problem, i.e., estimating the thermal properties after the frequency scan has been obtained. The present work involves finding the unknown thermal conductivity and volumetric heat capacity of the FGMs by using finite volume method. By taking the flux entering the sample as periodic and solving the discretized 1-D thermal wave field equation at a frequency domain, one can obtain the complex temperatures at the surface of the sample for each frequency. These complex temperatures when solved for a range of frequencies gives the phase vs frequency scan which can then be compared to original frequency scan obtained from the PTR experiment by using a residual function. Brute force and gradient descent optimization methods have been implemented to estimate the unknown thermal conductivity and volumetric specific heat of the FGMs through minimization of the residual function. In general, the spatial composition profile of the FGMs can be approximated by using a smooth curve. Three functional forms namely Arctangent curve, Hermite curve, and Bezier curve are used in approximating the thermal conductivity and volumetric heat capacity distributions in the FGMs. The use of Hermite and Bezier curves gives the flexibility to control the slope of the curve i.e. the thermal property distribution along the thickness of the sample. Two-layered samples with constant thermal properties and three layered samples in which one of the layer has varying thermal properties with respect to thickness are considered. The program is written in Fortran and several test runs are performed. Results obtained are close to the original thermal property values with some deviation based on the stopping criteria used in the gradient descent algorithm. Calculating the gradients at each iteration takes considerable amount of time and if these gradient values are already available, the problem can be solved at a faster rate. One of the methods is extending automatic differentiation to complex numbers and calculating the gradient values ahead; this is left for future work.
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