New Studies on Thermal Transport in Metal Additive Manufacturing Processes and Products

Wei, William Lien Chin

01 August 2017

Additive manufacturing (AM) is a manufacturing technique that adds material, such as polymers, ceramics, and metals, in patterned layers to build three-dimensional parts for applications related to medicine, aviation, and energy. AM processes for metals like selective laser melting (SLM) hold the unique advantage of fabricating metal parts with complex architectures that cannot be produced by conventional manufacturing techniques. Thermal transport can be a focal point of unique AM products and is likewise important to metal AM processes. This dissertation investigates AM metal meshes with spatially varied thermal conductivities that can be used to maximize the charge and discharge rates for thermal energy storage and thermal management by phase change materials (PCMs). Further, manufacturing these meshes demands excellent thermal control in the metal powder bed for SLM processes. Since the thermal conductivities of metal powders specific to AM were previously unknown, we made pioneering measurements of such powders as a function of gas infiltration. In the past, thermal transport was improved in phase change materials for energy storage by adding spatially homogeneous metal foams or particles into PCMs to create composites with uniformly-enhanced (UE) thermal conductivity. Spatial variation can now be realized due to the emergence of metal AM processes whereby graded AM meshes are inserted into PCMs to create PCM composites with spatially-enhanced (SE) thermal conductivity. As yet, there have been no studies on what kind of spatial variation in thermal conductivity can further improve charge and discharge rates of the PCM. Making such mesh structures, which exhibit unsupported overhangs that limit heat dissipation pathways during SLM processes, demands understanding of heat diffusion within the surrounding powder bed. This inevitably relies on the precise knowledge of the thermal conductivity of AM metal powders. Currently, no measurements of thermal conductivity of AM powders have been made for the SLM process. In chapter 2 and 3, we pioneer and optimize the spatial variation of metal meshes to maximize charge and discharge rates in PCMs. Chapter 2 defines and analytically determines an enhancement ratio of charge rates using spatially-linear thermal conductivities in Cartesian and cylindrical coordinates with a focus on thermal energy storage. Chapter 3 further generalizes thermal conductivity as a polynomial function in space and numerically optimizes the enhancement ratio in spherical coordinates with a focus on thermal management of electronics. Both of our studies find that higher thermal conductivities of SE composites near to the heat source outperform those of UE composites. For selected spherical systems, the enhancement ratio reaches more than 800% relative to existing uniform foams. In chapter 4, the thermal conductivities of five metal powders for the SLM process were measured using the transient hot wire method. These measurements were conducted with three infiltrating gases (He, N2, and Ar) within a temperature range of 295-470 K and a gas pressure range of 1.4-101 kPa. Our measurements indicate that the pressure and the composition of the gas have a significant influence on the effective thermal conductivity of the powder. We find that infiltration with He provides more than 300% enhancement in powder thermal conductivity, relative to conventional infiltrating gases N2 and Ar. We anticipate that this use of He will result in better thermal control of the powder bed and thus will improve surface quality in overhanging structures.

Additive Manufacturing

Phase Change Materials

Spatial Enhancement

Thermal Conductivity

Thermal Management

Thermal Transport

Phase change materials and thermal performance of buildings in Cyprus

Ozdenefe, Murat

January 2013

This work investigates the thermal performance of buildings in Cyprus and application of a particular passive technology; Phase Change Materials (PCMs) for the ultimate aim of reducing indoor air temperatures and energy supplied for the cooling season.PCMs for passive building applications are emerging technology and have not been tested for the buildings of Cyprus neither by computer simulations nor by practical applications. In this work, particular PCM end product; wallboard, having phase change temperature of 26 oC is employed together with various construction materials and simulated for buildings of Cyprus. Description of the current state in Cyprus has been carried out in terms of low energy building studies, widely used building fabric and building statistics. There is a huge gap in Cyprus in the field of energy performance and thermal comfort of buildings, which creates big room for research. Climatic design of buildings has been abandoned resulting in poor thermal comfort and increased energy consumption. There is still no regulation in place regarding the thermal performance of buildings in North Cyprus.Recent weather data of different Cyprus locations has been investigated and compared with the simulation weather data files that are employed in this work. The author has demonstrated that Finkelstein-Schafer statistics between recent weather data of Cyprus and simulation weather data files are close enough to obtain accurate results.Dynamic thermal simulations has been carried out by using Energy Plus, which is a strong and validated thermal simulation program that can model PCMs. Simulations are done for two different building geometry; “simple building” and “typical building” by employing different construction materials. Simple building is a small size box shaped building and typical building is a real existing building and selected by investigation of the building statistics.Simulation results showed that with this particular PCM product, indoor air temperatures and cooling energies supplied to simple building is reduced up to 1.2 oC and 18.64 % when heavier construction materials are used and up to 1.6 oC and 44.12 % when lighter construction materials are used. These values for typical building are found to be 0.7 oC, 3.24 % when heavier construction materials are used and 1.2 oC, 3.64 % when lighter construction materials are used. It is also found that, if thinner walls and slabs are used in the buildings the effectiveness of the PCM lining increases in significant amount.

624.1

Création et caractérisation d'un matériau de construction composite incorporant un nouveau matériau à changement de phase solide-solide / Creation and characterization of a building material with a new solid-solid phase change material

Harle, Thibault

14 November 2016

Dans le cadre de la réduction des consommations d'énergies primaires des bâtiments, de nouveaux matériaux de constructions sont amenés à être développés. Les réglementations thermiques poussent les nouvelles constructions à être économes en énergie. Elles doivent aussi être moins impactantes sur l'environnement tout en garantissant le confort des occupants.Dans ce travail est présenté le développement d'un nouveau matériau de construction composite intégrant un matériau à changement de phase (MCP).Les MCP sont capables d'échanger passivement de l'énergie thermique avec leur environnement. Il permettent ainsi une régulation passive de la température intérieure.Suite à un état de l'art, sur les MCP et le plâtre, est présenté la synthèse et la caractérisation physico-chimique d'un nouveau MCP à transition solide-solide.L'incorporation du MCP préalablement synthétisé à un matériau de construction de type plâtre est ensuite développée. Le matériau composite ainsi obtenu est caractérisé thermiquement et mécaniquement.Dans un dernier temps des évaluations environnementales du MCP et du matériau composite sont réalisées. / In a context of reduction of energy consumption in buildings, new buildings materials are developed. Thermal regulations require energy efficiency to buildings. They must be less impacting on the environment while ensuring occupant comfort.In this work is presented the development of a new composite building material incorporating a phase change material.PCM are able to exchange passively heat energy with their environment. It thus allow a passive control of the interior temperature of buildings.After a state of the art on PCM and plaster, a part is dedicated to synthesis and physicochemical characterisation of a new solid/solid PCM. In a third part the incorporation of the PCM previously synthesized in plaster is then developped. The composite material is mechanically and thermally characterized.In a last time environmental assessments of the PCM and the composite material are performed.

Matériaux à changement de phases

Régulation de la température

Polymères

Impacts environnementaux

Phase change materials

Temperature regulation

Polymers

Environmental assessment

Comparison of Sensible Water Cooling, Ice building, and Phase Change Material in Thermal Energy Storage Tank Charging: Analytical Models and Experimental Data

Caliguri, Ryan P.

04 October 2021

No description available.

Mechanical Engineering

Thermal Energy Storage

HVAC

Ice Storage

Chilled Water

Phase Change Materials

Cold Storage

Structural, optical and switching properties of epitaxial Ge-Sb-Te thin films

Behrens, Mario

10 March 2020

This thesis is devoted to the fabrication, optical characterization and switching behaviour of the prototypical chalcogenide-based phase-change material Ge2Sb2Te5, which is employed in non-volatile optical and electrical data storage devices. While common studies on conventional memory applications of Ge2Sb2Te5 are based on reversible amorphous to polycrystalline phase transitions, this thesis particularly focuses on the use of Ge2Sb2Te5 thin films of epitaxial, single-crystalline like nature aiming to gain deeper insights into structure-property correlations and novel switching pathways. The first part of this thesis deals with the growth of epitaxial Ge2Sb2Te5 thin films on Si(111) substrates by pulsed laser deposition with strong emphasis on controlling the degree of structural order in the thin films resulting from the distribution of intrinsic vacancies in the crystalline state of the material. As a result, highly vacancy-ordered epitaxial Ge2Sb2Te5 thin films in the thermodynamically stable as well as in the metastable crystalline phase are obtained, possessing a pronounced nanostructuring due to periodically spaced Van-der-Waals gaps or vacancy layers. Besides that, epitaxial Ge2Sb2Te5 thin films with complete disordered vacancy distributions are realized. Based on the achieved single-phase quality of the epitaxial thin films, a classification of the optical property contrast of different crystalline Ge2Sb2Te5 phases with respect to their vacancy ordering is presented. Beyond that, the impact of vicinal substrate surfaces on the phase, structure as well as on surface pattern formation in epitaxial Ge2Sb2Te5 thin films is investigated. The second part of this thesis employs epitaxial Ge2Sb2Te5 thin films as a model system to follow ns-laser induced structural modifications ranging from reversible crystalline to amorphous phase transitions to interface assisted epitaxial recrystallization processes. In particular, by applying single ns-laser pulses to the thin films, the transition from the vacancy ordered stable to the vacancy disordered metastable crystalline structure of Ge2Sb2Te5 via a transient molten phase is realized while the epitaxial nature of the thin films is preserved. This transition mechanism provides access to ultrafast crystal growth dynamics in an epitaxial phase-change material thin film model system offering the advantage of high crystalline quality and application-relevant sizing. By introducing a method that combines time-resolved reflectivity measurements with high resolution scanning transmission electron microscopy, crystal growth velocities upon fast cooling after single ns-laser pulse irradiation are determined. As a result, an increase in crystal growth velocity from 0.4 to 1.7 m/s with increasing laser fluence is observed with the maximum rate of 1.7 m/s as the upper detectable limit of the studied material.

Phase-change materials epitaxy

info:eu-repo/classification/ddc/530

ddc:530

Nanopatterning of Phase Change Material Ge2SbTe5 towards Novel and Improved Reconfigurable Photonic Devices

Burrow, Joshua A.

January 2021

No description available.

Optics

Physics

Phase Change Materials for Optoelectronic Devices and Memories: Characterization and Implementation

Sevison, Gary A.

06 January 2022

No description available.

Optics

Phase Change Materials

PCMs

Photonics

GST

SLM

Spatial Light Modulator

Photonic Devices

THERMAL ENERGY STORAGE WITH MULTIPLE FAMILIES OF PHASE CHANGE MATERIALS (PCM)

Elsanusi, Omer

01 September 2020

The world is facing a major challenge when it comes to proper energy utilization. The increasing energy demand, the depleting fossil fuel resources and the growing environmental and ecological concerns are factors that drive the need for creative solutions. Renewable energy resources such as solar sit in the center of these solutions. Due to their intermittent nature, development of energy storage systems is crucial. This dissertation focused on the latent thermal energy storage systems that incorporate phase change materials (PCM). The main goal was to enhance the heat transfer rates in these systems to address the low melting (energy storage stage) and solidification (recovery stage) rates that are caused by the PCMs’ low thermal conductivity values. The application of multiple PCMs (m-PCMs) with varying melting temperatures in several arrangements was investigated. The effects of applying m-PCMs on the conduction heat transfer and on the natural convection heat transfer in both horizontally and vertically oriented heat exchangers were studied. This was followed by an optimization study of the PCMs’ melting temperatures and the working fluid flow rate. Further heat transfer enhancement using metal fins was also investigated. Numerical models were developed and validated. Results are reported and discussed. Significant enhancement in both complete melting time and energy storage capacity was obtained by the m-PCMs in series arrangement. This enhancement is more pronounced in the vertically oriented system. The working fluid flow rate was found to have a limited effect during the melting stage. However, it seems to be crucial in the solidification stage.

Conduction

Convection

Energy Storage

Heat Exchanger

Phase Change Materials

Renewable energy

Numerical Modeling of the Effects of Micro-Encapsulated Phase Change Materials Intermixed with Grout in Vertical Borehole Heat Exchangers

Aljabr, Ahmad

09 August 2021

No description available.

Mechanical Engineering

Energy

Geophysics

GCHP

Phase Change Materials

Geothermal

Heat pump

Characterization and Controllable Nucleation of Supercooled Metallic Phase Change Materials

Elston, Levi Jerome

15 May 2023

No description available.

Mechanical Engineering

gallium

phase change materials

supercooling

nucleation

thermal management

electronics cooling