Photovoltaic–thermoelectric temperature control using a closed-loop integrated cooler

The Closed-Loop Integrated Cooler (CLIC) is a novel technique deployed on experimental apparatus to accurately measure, monitor and control the temperature of optoelectronic devices. Demonstrated here within a Concentrator Photovoltaic-Thermoelectric (CPV-TE) hybrid device, the thermoelectric module was used as a solid state sensor and heat pump in order to control the operational temperature for a triple-junction solar cell. The technique was used to achieve stable, reproducible and repeatable Standard Test Conditions (STC) of 25oC cell temperature, with 1000W/m2 irradiance and AM1.5G spectrum. During testing with Secondary Optical Element (SOE) optics in a solar simulator, the CLIC enabled accurate temperature control of the CPV cell. This would otherwise be unfeasible due to the spectral, reflective and diffusive effects of the SOE optics. The CLIC was used to obtain temporal and spatial constant temperature of the CPV-TE hybrid receiver during Current-Voltage measurement. This method highlights the future potential of the CLIC for accurate temperature control of optoelectronic devices both during testing and in future semiconductor device applications where temperature control is essential to performance or lifetime

Systems integration of concentrator photovoltaics and thermoelectrics for enhanced energy harvesting

Alongside other photovoltaic technologies, Concentrator photovoltaics (CPV) capitalise on the recent progress for high-efficiency III:V based multi-junction photovoltaic cells, combining them with low cost optics for increased power production. Thermoelectrics are semiconductor devices that can act as solid-state heat pumps (Peltier mode) or to generate electrical power from temperature differentials (Seebeck effect). In this work, new designs for the integration of a thermoelectric module within a CPV cell receiver were proposed and substantiated as a reliable and accurate temperature control platform. The thermoelectric was used for accurate and repeatable cooling, exhibiting high temporal-thermal sensitivity. Testing was done under varying irradiance and temperature conditions. A novel Closed Loop Integrated Cooler (CLIC) technique was tested, demonstrated and validated as a useful experimental metrology tool for measuring sub-degree cell temperature within hybrid devices using the material properties of the thermoelectric module. Proof-of-concept circuitry and a LabVIEW based deployment of the technique were designed built and characterised. The technique was able to detect thermal anomalies and fluctuations present when undertaking an I-V curve, something otherwise infeasible with a standard k or t-type thermocouple. A full CPV-TE hybrid module with primary and secondary optical elements (POE-SOE-CPV-TE) was built using a further optimised receiver design and tested on-sun for evaluation under outdoor operation conditions in southern Spain. A unique TE-based “self-soldering” process was investigated to improve manufacture repeatability, reproducibility and minimise thermal resistance. A manually-tracked gyroscopic test rig was designed, built and used to gain valuable outdoor baseline comparison data for a commercially available CPV module and a Heterojunction Intrinsic Thinlayer (HIT) flat plate panel with the POE-SOE-CPV-TE hybrid device. An energetic break-even between the power consumed by the TE and the power gain of the CPV cell from induced temperature change was experimentally measured. This work demonstrated the unique functionalities a thermoelectric device can improve CPV power generation. The potential of a TEM to improve CPV power generation through active cooling was highlighted and quantified

Design and characterization of hybrid III–V concentrator photovoltaic–thermoelectric receivers under primary and secondary optical elements

Lattice-matched monolithic triple-junction Concentrator Photovoltaic (CPV) cells (InGa(0.495)P/GaIn(0.012)As/Ge) were electrically and thermally interfaced to two Thermoelectric (TE) Peltier module designs. An electrical and thermal model of the hybrid receivers was modelled in COMSOL Multiphysics software v5.3 to improve CPV cell cooling whilst increasing photon energy conversion efficiency. The receivers were measured for current-voltage characteristics with the CPV cell only (with sylguard encapsulant), under single secondary optical element (SOE) at x2.5 optical concentration, and under Fresnel lens primary optical element (POE) concentration between x313 and x480. Measurements were taken in solar simulators at Cardiff and Jaén Universities, and on-sun with dual-axis tracking at Jaén University. The hybrid receivers were electrically, thermally and theoretically investigated. The electrical performance data for the cells under variable irradiance and cell temperature conditions were measured using the integrated thermoelectric module as both a temperature sensor and as a solid-state heat pump. The performance of six SOE-CPV-TE hybrid devices were evaluated within two 3-receiver strings under primary optical concentration with measured acceptance angles of 1.00o and 0.89o, similar to commercially sourced CPV modules. A six-parameter one-diode equivalent electrical model was developed for the multi-junction CPV cells with SOE and POE. This was applied to extract six model parameters with the experimental I-V curves of type A receiver at 1, 3 and 500 concentration ratios. Standard test conditions (1000W/m2, 25oC and AM1.5G spectrum) were assumed based on trust-region-reflective least squares algorithm in MATLAB. The model fitted the experimental I-V curves satisfactorily with a mean error of 4.44%, and the optical intensity gain coefficient of SOE and POE is as high as 0.91, in comparison with 0.50-0.86 for crossed compound parabolic concentrators (CCPC). The determined values of diode reverse saturation current, combined series resistance and shunt resistance were similar to those of monocrystalline PV cell/modules in our previous publications. The model may be applicable to performance prediction of multi-junction CPV cells in the future

A scaling law for monocrystalline PV/T modules with CCPC and comparison with triple junction PV cells

Scaling laws serve as a tool to convert the five parameters in a lumped one-diode electrical model of a photovoltaic (PV) cell/module/panel under indoor standard test conditions (STC) into the parameters under any outdoor conditions. By using the transformed parameters, a current-voltage curve can be established under any outdoor conditions to predict the PV cell/module/panel performance. A scaling law is developed for PV modules with and without crossed compound parabolic concentrator (CCPC) based on the experimental current-voltage curves of six flat monocrystalline PV modules collected from literature at variable irradiances and cell temperatures by using nonlinear least squares method. Experiments are performed to validate the model and method on a monocrystalline PV cell at various irradiances and cell temperatures. The proposed scaling law is compared with the existing one, and the former exhibits a much better accuracy when the cell temperature is higher than 40 °C. The scaling law of a triple junction flat PV cell is also compared with that of the monocrystalline cell and the CCPC effects on the scaling law are investigated with the monocrystalline PV cell. It is identified that the CCPCs impose a more significant influence on the scaling law for the monocrystalline PV cell in comparison with the triple junction PV cell. The proposed scaling law is applied to predict the electrical performance of PV/thermal modules with CCPC

It’s more than money: policy options to secure medical specialist workforce for regional centres

Objectives Regional centres and their rural hinterlands support significant populations of non-metropolitan Australians. Despite their importance in the settlement hierarchy and the key medical services provided from these centres, little research has focused on their issues of workforce supply and long-term service requirements. In addition, they are a critical component of the recent growth of 'regional' hub-and-spoke specialist models of service delivery.Methods The present study interviewed 62 resident specialists in four regional centres, seeking to explore recruitment and retention factors important to their location decision making. The findings were used to develop a framework of possible evidence-informed policies.Results This article identifies key professional, social and locational factors, several of which are modifiable and amenable to policy redesign, including work variety, workplace culture, sense of community and spousal employment; these factors that can be targeted through initiatives in selection, training and incentives.Conclusions Commonwealth, state and local governments in collaboration with communities and specialist colleges can work synergistically, with a multiplicity of interdigitating strategies, to ensure a positive approach to the maintenance of a critical mass of long-term rural specialists.What is known about the topic? Rural origin increases likelihood of long-term retention to rural locations, with rural clinical school training associated with increased rural intent. Recruitment and retention policy has been directed at general practitioners in rural communities, with little focus on regional centres or medical specialists.What does this study add? Rural origin is associated with regional centre recruitment. Professional, social and locational factors are all moderately important in both recruitment and retention. Specialist medical training for regional centres ideally requires both generalist and subspecialist skills sets. Workforce policy needs to address modifiable factors with four groups, namely commonwealth and state governments, specialist medical colleges and local communities, all needing to align their activities for achievement of long-term medical workforce outcomes.What are the implications for practitioners? Modifiable factors affecting recruitment and retention must be addressed to support specialist models of care in regional centres. Modifiable factors relate to maintenance of a critical mass of practitioners, training a fit-for-purpose workforce and coordinated effort between stakeholders. Although remuneration is important, the decision to stay relates primarily to non-financial factors

In-situ thermoelectric temperature monitoring and “Closed-loop integrated control” system for concentrator photovoltaic-thermoelectric hybrid receivers

This work demonstrates a new technique that capitalizes on the inherent flexibility of the thermoelectric module to provide a multifunctional platform, and exhibits a unique advantage only available within CPV-TE hybrid architectures. This system is the first to use the thermoelectric itself for hot-side temperature feedback to a PID control system, needing no additional thermocouple or thermistor to be attached to the cell - eliminating shading, and complex mechanical designs for mounting. Temperature measurement accuracy and thermoelectric active cooling functionality is preserved. Dynamic “per-cell” condition monitoring and protection is feasible using this technique, with direct cell-specific temperature measurement accurate to 1°C demonstrated over the entire experimental range. The extrapolation accuracy potential of the technique was also evaluated

Novel hybrid III:V concentrator photovoltaic-thermoelectric receiver designs

This paper presents the design, manufacture and electrical characterization of novel hybrid III:V Concentrator Photovoltaic-Thermoelectric receivers. Addition of an encapsulating and spectral homogenizing single active surface secondary optic lens increased the solar cell electrical power output from 7.66mW (ALPHA no cooling) to 18.20mW (KAPPA with TE cooling). The effective optical concentration of the optics, based on short circuit current, was x2.4. A linear irradiance vs maximum power receiver output relationship was observed (R2=0.9978), confirming good optical alignment during manufacture and likewise internal current matching of the series-connected triple-junction cell. An in-depth COMSOL model for simulated evaluation of the synergistic thermally-dependent parameters inherent to hybrid devices was built and experimentally validated

Experimental comparison of a III:V triple-junction concentrator photovoltaic-thermoelectric (CPV-TE) hybrid module with commercial CPV and flat plate silicon modules

Concentrator Photovoltaic-Thermoelectric (CPV-TE) hybrid devices have the potential to address areas of limitation within concentrator photovoltaic devices, using the inherent flexibility and controllability of thermoelectrics. In this work, a full CPV-TE module was designed and fabricated using commercial Primary and Secondary Optical Elements (POEs and SOEs respectively). The SOE-CPV-TE hybrid receivers were characterized prior to integration within the module, and connected into a string of three receivers. The acceptance angle of the POE-SOE-CPV-TE hybrid module was experimentally characterized, and outdoor on-tracker data was obtained at the University of Jaén. For the first time, the performance of CPV-TE hybrid devices was evaluated within a 3-receiver string, and the efficiency of on-sun TE cooling was investigated.A preliminary break-even point was found at 0.3A, for active cooling verses non- cooling for the CPV-TE hybrid receivers. This highlights the future on-sun performance increases possible with further optimised CPV-TE module designs, including a low-power regime for optimised TE operation