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6. Embodied impacts of key materials for UK decarbonised domestic retrofit: Differences between sources of embodied carbon and embodied energy data.

Author

Hurst, Lois J. and O'Donovan, Tadhg S.

Subjects
*GREENHOUSE gas mitigation, *CARBON analysis, *CONSTRUCTION materials, *CARBON cycle, *INFORMATION design
Abstract

• Smaller/lighter materials which dominate retrofit are poorly characterised in datasets. • Materials are poorly named, described, or are absent in LCA datasets. • LCA for retrofit may not yield reliable information for design decisions. • Embodied energy coefficients may be more reliable than embodied carbon ones. • Reporting only carbon could lead to externalisation of impacts, not avoidance. Low energy domestic retrofit consumes materials, such as insulation, membranes and glazing, with smaller quantities of structural timber, steel or concrete, which have associated embodied impacts from resource extraction, manufacture and end-of-life treatments. In retrofit design, coefficients for material embodied impacts vary widely between sources and can lead to different results in a life cycle energy or carbon analysis, and perhaps different material choices in retrofit implementation. This paper considers how and why results differ between sources, and whether such data is suitable for making climate-beneficial design decisions. Embodied energy and carbon coefficients for 18 key retrofit materials were obtained from two widely used LCA databases and their similarity was quantified. The data collected illustrates that 70% embodied energy and embodied carbon data is within 20%, but that 30% of data was more than 20% different. Consistency of product naming and the absence in the datasets of key retrofit materials are factors identified contributing to variation, and present real constraints in practice. Furthermore, this exercise showed that embodied impacts for the types of materials most prominent in retrofits are less-well characterised than other major construction materials, and presents another layer of uncertainty. The data showed embodied energy was more consistent between sources than embodied carbon. This raises doubts about the predominant use of embodied carbon over energy for such analyses and establishes that a focus on embodied carbon over embodied energy has less power to reduce greenhouse gas emissions than considering both metrics together. It is concluded that obtaining such data with confidence is challenging and requires expertise in LCA, and is therefore unlikely to be accessible to most retrofit designers. Datasets need to be more complete and offer higher confidence to ensure delivery of high quality and meaningful results for climate-beneficial design decisions. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Thermal performance predictions and tests of a novel type of flat plate solar thermal collectors by integrating with a freeze tolerance solution

Author

Deng, Jie, O'Donovan, Tadhg S., Tian, Zhiyong, King, Josh, and Speake, Stuart

Abstract

A novel design concept of Flat Plate Solar Collectors (FPSCs) is conceived and developed by integrating with a freeze-tolerant (so-called 'ice immune') solution using flexible silicone tubing. It is intended to directly run water in the solar thermal systems with the FPSCs instead of using expensive anti-freeze fluids, and to remove secondary heat transfer facilities (e.g. an extra tank with a buried heat exchanger). Successful development of such kind of solar thermal collectors will enable a reduction of installed cost of conventional solar thermal systems without needing secondary heat transfer facilities. In the prophase design, thermal performances of FPSCs with two configurations, i.e. the serpentine tube type and the header riser type, were predicted based on the collector lumped thermal capacitance model alongside CFD (Computational Fluid Dynamics) calculations. Then two prototypes of FPSCs with the ice-immune silicone tubing (one AES serpentine tube type, one modified Chinese micro-heat-pipe-array panel) were made to determine the collector performance and compared to an original AES solar keymark reference panel via experimental tests. The results show that the Chinese micro-heat-pipe-array panel performs better than the AES header riser solar keymark panel in terms of flow rate per m2 collector aperture area, while the AES serpentine tube panel with silicone tubing performs somewhat lower than the solar keymark with T_m^*≤0.035 and better than the solar keymark when T_m^*>0.035. The serpentine tube panel and the Chinese micro-heat-pipe-array panel both integrated with silicone tubing for freeze tolerance are proven to be effective as the modification doesn’t compromise the collector thermal performance markedly.

Published
2019

10. Performance of a concentrating photovoltaic monomodule under real operating conditions: Part II – Power rating

Author

Theristis, Marios, Fernández, Eduardo F., Georghiou, George E., O'Donovan, Tadhg S., Georghiou, George E. [0000-0002-5872-5851], and Theristis, Marios [0000-0002-7265-4922]

Subjects
Engineering, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Photovoltaic system, Energy Engineering and Power Technology, 02 engineering and technology, 021001 nanoscience & nanotechnology, Concentrator, Power (physics), Fuel Technology, Power rating, Nuclear Energy and Engineering, 0202 electrical engineering, electronic engineering, information engineering, Standard test, Solar simulator, Sensitivity (control systems), 0210 nano-technology, business, Spectral factor, Simulation
Abstract

In Part I of this work, a comprehensive outdoor characterisation of a concentrating photovoltaic monomodule was presented where the importance of atmospheric parameters on the performance of such systems was highlighted. In this work, Part II, the power ratings of a concentrating photovoltaic monomodule are determined using different methods and filtering criteria that account for the spectrum. Spectral variations are considered to be a major parameter that contributes to the uncertainty of concentrating photovoltaic power ratings due to the dynamic behaviour of outdoor conditions. In order to address the sensitivity of such variations, Concentrator Standard Operating Conditions (CSOC) and Concentrator Standard Test Conditions (CSTC) power rating estimations are performed using different scenarios and compared with measurements obtained using a Helios 3198 solar simulator. The application of different methods and filtering criteria, in terms of the spectral matching ratio (SMR) of the middle to bottom subcell, exhibits differences of up to 3.64% and 1.37% for the CSOC and CSTC estimations respectively. The comparison with the CSTC power rating obtained indoors shows a difference of up to 8.45%; this is attributed to the tracking errors and also the temperature dependence of the refractive optics. The application of the spectral factor (SF) as filtering criterion reduces the CSTC power rating difference to 6.74% compared to the corresponding value obtained indoors. In addition, the CSOC power rating estimation using the SF filtering exhibits similar results to the standardised procedure using the SMR indices (within 1.21%).

Published
2018

13. High Dynamic Velocity Range Particle Image Velocimetry Using Multiple Pulse Separation Imaging.

Author

Persoons, Tim and O'Donovan, Tadhg S.

Subjects
*PARTICLE image velocimetry, *MAGNITUDE estimation, *ALGORITHMS, *TURBULENCE, *LASER Doppler velocimeter
Abstract

The dynamic velocity range of particle image velocimetry (PIV) is determined by the maximum and minimum resolvable particle displacement. Various techniques have extended the dynamic range, however flows with a wide velocity range (e.g., impinging jets) still challenge PIV algorithms. A new technique is presented to increase the dynamic velocity range by over an order of magnitude. The multiple pulse separation (MPS) technique (i) records series of double-frame exposures with different pulse separations, (ii) processes the fields using conventional multi-grid algorithms, and (iii) yields a composite velocity field with a locally optimized pulse separation. A robust criterion determines the local optimum pulse separation, accounting for correlation strength and measurement uncertainty. Validation experiments are performed in an impinging jet flow, using laser-Doppler velocimetry as reference measurement. The precision of mean flow and turbulence quantities is significantly improved compared to conventional PIV, due to the increase in dynamic range. In a wide range of applications, MPS PIV is a robust approach to increase the dynamic velocity range without restricting the vector evaluation methods. [ABSTRACT FROM AUTHOR]

Published
2011
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14. Performance analysis and characterisation of a high concentrating solar photovoltaic receiver

Author

Maka, Ali Omar Mohamed, O'Donovan, Tadhg S., and Bennat, Nick

Abstract

Solar energy is deemed to be one the most efficient and clean energy resources to generate electricity. Photovoltaic technologies have a promising future in space and terrestrial applications. Photovoltaic concentrating is a technique to increase the conversion efficiency of high-efficiency solar cells. Multi-junction solar cells are designed to exploit a larger range of solar spectrum photons and convert to electricity. In this study, triple-junction III-V solar cells compound consisting of GaInP/GaInAs/Ge semiconductor materials is considered. This work investigates terrestrial multi-junction solar cells performance characterisation, which is important for the design of high concentration photovoltaic systems. The research has developed a model of a III-V solar cell operating at high flux conditions induced by light concentration. The thermal management on such an assembly is a focus of this work. This research also presents the effects of Air Mass (AM) on solar cell performance. This atmospheric parameter has a strong influence on the behaviour of high concentrating photovoltaic solar cells. As air mass increases, the corresponding Direct Normal Irradiance (DNI) and Cell Temperature (Tc) decrease. The effects of air mass (AM =1-10D) atmospheric changes on triple-junction solar cells have been assessed. For High Concentration Photovoltaic (HCPV) the light concentration on to a relatively small solar cell area leads to high power densities. Effective thermal management is essential to avoid damaging high temperatures. A thermal model by using a convergent iterative technique has been developed; the predicted convergent cell temperature limit is ≤ 80oC. The proportion of the incident radiation not converted to electricity leads to the generation of heat; this is a function of material temperature coefficients and current mismatch in variable atmospheric conditions and results in an increase in cell temperature. The rate of heat loss by convective transfer is also considered for air mass values AM =1.5, 4 and 8D. In addition, a Finite Element Method (FEM) model is developed in COMSOL Multiphysics® in order to predict the temperature distribution of the PV cells and thermal behaviour of the receiver assembly. Furthermore, in this study, a transient model of the HCPV cell has been developed using MATLAB® Live-Link with COMSOL Multiphysics. In order to characterise the behaviour of a triple-junction solar cell, it is essential to find the transient cell operating temperature. The behaviour of electrical parameters of the Jsc, Voc, FF and conversion efficiency are considered. However, in the proposed model, a dynamical efficiency is compared with constant efficiency and the error is about 12%. The research has given a better understanding of the overall daily/annual performance prediction of CPVs and is important for future system design in variable environment conditions. At higher values of DNI, Tamb and lower AM the thermal response needs enhanced/forced convection to maintain cell operation within/below safe operating temperature and to optimise energy yield. For long-term performance evaluation, the average of monthly variations of atmospheric parameters throughout the year is considered. Thus, during the summer months, a higher record of the atmospheric parameters values in which need more consideration. The annual cell operating temperature of ˃ 80oC represents about 13% of the time, which happened during the Summer season. As is noted, the cell temperature between 65-70°C is predominate in the Spring and Autumn seasons and represent about 24%, (the highest frequency).

Published
2020

15. Temperature control in a multi-tubular fixed bed Fischer-Tropsch reactor using encapsulated phase change materials

Author

Odunsi, Ademola O., O'Donovan, Tadhg S., and Reay, David A.

Subjects
662.6
Abstract

The Fischer-Tropsch synthesis is a highly exothermic, indirect, catalytic, gas (syngas) liquefaction chemical process. Temperature control is particularly critical to the process in order to ensure longevity of the catalyst, optimise the product distribution, and to ensure thermo-mechanical reliability of the entire process. This thesis proposes and models the use of encapsulated, phase change material, in conjunction with a supervisory temperature control mechanism, as diluents for the catalytic, multi-tubular fixed bed reactor in order to help mitigate the heat rejection challenges experienced in the process. The modelling was done using the Finite Element Analysis (FEA) software, COMSOL Multiphysics. In the main, three studies were considered in this thesis. In the first study, a two dimensional quasi-homogeneous, reactor model, without and with the dissipation of the enthalpy of reaction into a near isothermal phase change material (silica encapsulated tin metal) heat sink, in a wall-cooled, single-tube fixed bed reactor was implemented and the results were presented. The encapsulated phase change material was homogeneously mixed with the active catalyst pellets. The thermal buffering provided by the phase change material were found to induce up to 7% increase in selectivity towards the C5+ and a 2.5% reduction in selectivity towards CH4. Although there was a reduction in the conversion per pass of the limiting reactant and hydrocarbon productivity due to a reduction in reactor temperature, it was observed that for a unit molar reduction in the productivity of C5+, there was a corresponding 1.5 moles reduction in methane production. In the second study, a modified, one dimensional, α-model was derived which accounted for the heat sink effect of the phase change material diluent. The resulting, less computationally cumbersome, yet sufficiently accurate model was benchmarked against the more rigorous two-dimensional quasi-homogeneous model in order to check its fidelity in predicting the reactor performance. As in the first case study, a homogeneous distribution of the phase change material and active catalyst pellets was assumed. The α-model was able to approximate the reactor temperature profile of the 2D-quasi-homogeneous reactor model to within 4% error, and consistently, slightly over-predicted the limiting reactant conversion by about 3%. Based on these comparisons, the α-model was deemed sufficiently accurate to predict the reactor performance in place of the 2D model for the optimisation simulation in the third study. The third case study entailed simultaneously maximising the production of long chain hydrocarbon molecules and ensuring proper heat rejection from the reacting system, two desirable yet often conflicting operational requirements. The homogeneous distribution of the active catalyst pellets and the phase change material diluents was abandoned for a multi-zonal axial distribution in which, individual zones of the catalyst bed were diluted to varying extents. The best dilution and distribution "recipe" was determined using optimisation techniques and the previously derived modified α-model. The multi-zonal axial dilution of the catalyst bed brought about a marked increase (up to 19%) in the productivity of the long chain hydrocarbons, while ensuring a more judicious use of the catalyst bed in contrast to the homogeneous catalyst/phase change material arrangement in the previous two studies. The latent enthalpy of the metallic phase change material combined with its good thermal conductivity helped push the limits of the catalyst bed by increasing the conversion per pass beyond the typical 20-30% reported in literature, with less likelihood of either early catalyst deactivation or thermal unreliability of the reacting system. In the main, it was observed that the overall productivity of the desired C5+ could be enhanced by reducing the quantity of the catalyst pellets by a pre-defined reactor volume. In addition, the reactor productivity benefits from a highly active zone situated at the reactor entrance, immediately followed by a less reactive zone. This arrangement has the effect of ramping the reaction rate (and in effect the reactor temperature) early on, and this is kept in check by the less reactive zone immediately adjacent to the reactive one at the reactor entrance.

Published
2017

16. Development of a spectral dependent electrical & thermal model for high concentrating photovoltaic (HCPV) receivers

Author

Theristis, Marios, O'Donovan, Tadhg S., and Mallick, Tapas K.

Subjects
621.31
Abstract

High concentrating photovoltaic (HCPV) systems employ III-V multijunction (MJ) solar cells. Such solar cells are monolithically connected in-series and therefore present a strong dependence on the solar spectrum variations. In addition, the concentrated solar flux contributes to the heat generation within the solar cells and, in combination with the current mismatch between the subcells, can force the device to operate in elevated temperatures. It is important therefore, to investigate the influence of the atmospheric parameters on the electrical performance of HCPV and also to quantify the cooling requirements based on the spectrum changes. In this thesis, a spectral dependent electrical model has been developed to calculate the electrical characteristics and quantify the heat power of a multijunction solar cell. A three-dimensional finite element analysis is also used to predict the solar cell's operating temperature and cooling requirements for a range of ambient temperatures. The combination of these models improves the prediction accuracy of the electrical and thermal behaviour of triple-junction solar cells. The convective heat transfer coefficient between the back-plate and ambient air is quantified based on input spectra. A theoretical investigation is performed to analyse the influence of air mass (AM), aerosol optical depth (AOD) and precipitable water (PW) on the performance of each subcell and whole. It has been shown that the AM and AOD have a negative impact on the spectral and electrical performance of 3J solar cells while the PW has a positive effect, although, to a lesser degree. In order to get a more realistic assessment and also to investigate the effect of heat transfer coefficient on the annual energy yield, the methodology is applied to four US locations using data from a typical meteorological year (TMY3). The integrated modelling procedure is validated experimentally using field measurements from Albuquerque, NM. The importance of the effect of atmospheric parameters on the solar spectrum and hence the performance of HCPV systems is highlighted in this work. The outdoor characterisation provides with useful insight of the influence of spectrum on the performance of a HCPV monomodule and the current CSOC and CSTC ratings are evaluated based on different spectral filtering criteria.

Published
2016

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