Abstract
South Africa is the most technologically advanced nation in Africa. However, the country is plagued with constant load shedding. The country receives about 2500 sunshine hours annually, with daily average irradiation levels of 4.5–6.5 kWh/m2. Despite these potentials, the use of electricity for domestic water heating is still prevalent in the country. The mass rollout of solar water heating (SWH) technologies in the low-cost housing sector across the country were met with massive failures. This study aims to assess the energy yield of a passive flat plate and an evacuated tube solar water heating system by evaluating the performance of these systems to address the energy crisis in South Africa. The flat plate (FP) and evacuated tube (ET) solar water heating systems were monitored for four days, characterised by varying sky conditions through instantaneous data measurement at 5 s. The parameters measured were water temperature, ambient temperature, irradiance at the plane of array, relative humidity, wind speed and direction. The results obtained show that a maximum irradiance of 1050 W/m2 was obtained on a clear day and corresponded to a hot water temperature of about 58 °C and 65 °C for the FP and ET, respectively. However, a cloudy day with a maximum irradiance of 400 W/m2 produced about 22 °C and 29 °C of hot water for the FP and ET, respectively. The results obtained in this study will guide stakeholders in the renewable energy sector towards employing SWH systems to replace or augment the electric geyser. Solar water heaters (SWH) can be used in the low-cost housing sector to provide hot water. Hence, the assessments in this study offer essential information for the deployment of these systems to reduce demand on the ailing South African electricity utility, Eskom, and mitigate climate change.
Highlights
The International Energy Agency (IEA), from a global point of view, described solar heating and cooling technologies as “the sleeping giant of renewable energy potential” [1]
This study presented the relevance of evaluating the performance of flat plate and evacuated tube solar water heating systems and their usage profiles
A cloudy day with a maximum of 400 W/m2 irradiance corresponds to 24.84 ◦C and 28.32 ◦C of hot water produced for the flat plate (FP) and evacuated tube (ET), respectively
Summary
The International Energy Agency (IEA), from a global point of view, described solar heating and cooling technologies as “the sleeping giant of renewable energy potential” [1]. Solar energy is utilised to generate electricity, hot water and space heating. A brief policy report for South Africa on solar water heating technologies affirms three ways of converting harvested solar energy: electricity, hot water and space heating [3]. The report shows that solar water heaters and solar air collectors convert incident irradiance hot water and space heating, respectively, while photovoltaic modules convert solar irradiance to electricity. The development of a technology for hot water generation ensures the sun’s irradiance is adequately utilised [4]. Two concentrating solar power collectors’ (CSP) efficiency reduced significantly under low irradiance. The authors showed that utilising solar technologies reduces greenhouse gas emissions considerably while saving about 193 × 106 m3 of natural gas in south-central Iran. Lim et al [6]
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