Modelling and application of advanced thermal storage materials

Rawson, Anthony Joseph

Title: Modelling and application of advanced thermal storage materials
Creator: Rawson, Anthony Joseph
Relation: University of Newcastle Research Higher Degree Thesis
Resource Type: thesis
Date: 2016
Description: Research Doctorate - Doctor of Philosophy (PhD)
Description: Instantaneous availability of power is taken for granted in much of the developed world. Provided a fuel source is unlimited and readily available, the expectation of instant power is readily fulfilled with available technology. However, it is now accepted that human kind’s most utilised fuels (coal, oil and natural gas) are in fact diminishing and their availability cannot be guaranteed as demand outstrips supply. Not only supply limitations exist, the burning of these fuels contributes heavily to dangerous climate change. Thus technology needs to be developed to efficiently utilise fuels intermittently or take advantage of other energy sources which may also be intermittent. Thermal energy storage devices store heat energy through sensible heating, a phase change or a combination of the two. A device can be coupled to a power cycle to provide thermal inertia to the system. Power cycles that generate electricity from an intermittent heat source are an obvious application. Applications also exist in industrial processes requiring continuous heat for drying or a chemical reaction and control of air temperature in sensitive environments. Many thermal energy storage devices exist, tailored to particular temperature ranges and storage capacities. This thesis introduces the Miscibility Gap Alloy as a potential thermal storage technology. Miscibility Gap Alloys overcome a number of the shortcomings of molten salt, paraffin and sensible storage media but their properties are not yet well communicated. Material properties, lifetime estimates, economic characteristics and implementations of Miscibility Gap Alloys are discussed in this dissertation. Through analysis of these aspects a number of novel methodologies, theories and devices were developed. The Lattice Monte Carlo method was successfully employed to model effective conductivity of binary composites. The results of these analyses and existing homogenisation models were generalised for volume fraction and constituent conductivity ratio through a novel concept titled ‘microstructural efficiency’. This work enabled the effective thermal conductivity (and indeed any 2^nd rank tensor property obeying Fick’s Law) to be estimated with great accuracy for a number of idealised and common morphologies with generality in volume fraction and conductivity ratio of constituents. Best practice manufacturing methods for different Miscibility Gap Alloys were identified through experiment and presented. This led to knowledge of the morphology of the materials (including potential porosity). From this, good estimates were made of all material properties relevant to the alloys use as thermal storage. The hypothesised material property advantages of Miscibility Gap Alloys are thus confirmed and compared with the existing state of the art. A discussion of the long term behaviour of Miscibility Gap Alloys follows. Consideration is given to diffusion as well as mechanical and chemical dominated aging mechanisms. It was found that diffusion dominated aging is most likely for systems with non-negligible solubility of the components and where discrete large powders undergo large temperature changes through cycling. Mechanical effects should not contribute beyond the first few cycles as the matrix deforms to accommodate any mismatch in thermal expansion. Chemical aging is likely for systems exposed to air or water but may be mitigated through isolation of the material. Establishment of material and long term properties of the alloys enables a discussion of the comparative economics of using Miscibility Gap Alloys as thermal storage. The alloys are shown to be extremely competitive compared to existing thermal energy storage solutions. They have a higher capital cost generally, due to the high cost of metals. However, the infrastructure and maintenance costs required are a fraction of that for most other thermal storage media. Finally a number of potential implementations are introduced ranging from thermal inertia for power production to heating for the drying of foods. Detailed calculations and engineering drawings are provided for an air heater device intended for room heating. Specific methods of storage for concentrated solar thermal plants are described before more exotic implementations are presented. The thesis concludes with a summary of work and a critical evaluation of the potential of Miscibility Gap Alloys as thermal storage media. Potential work for future research is provided with guidance as to how it might be initiated.
Subject: miscibility gap alloy; thermal storage; microstructural efficiency
Identifier: http://hdl.handle.net/1959.13/1317504
Identifier: uon:23431
Language: eng
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