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An Investigation to Enhance Stratification in Solar Domestic Hot Water Tanks Using Photovoltaic Power

Date

2019-09-24T12:50:05Z

Authors

Taher, Araf

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Abstract

Improved energy conservation methods and awareness of these methods in the industrial sector, along with the decreasing cost of photovoltaic (PV) technology, implicates PV-water heating system designs as economically sustainable alternatives to traditional methods for domestic hot water systems (DHWS). The proper design for an electric resistance immersion heater element in a thermo-syphon side-arm storage tank using PV power heating has not yet been determined. This research is an experimental investigation to evaluate the proper design of a thermo-syphon side-arm storage tank using PV-heating, with longitudinally perforated manifolds that work with standard Canadian domestic solar hot water tanks under different climate conditions in Halifax, Nova Scotia. The evaluation of the performance of the hot water inlet devices was based on the assessments of flow visualization, temperature distributions inside the storage tank, degrees of stratification (DOS), availability, availability ratio, energy delivery, entropy ratio, merit factor and internal entropy generation. The most effective hot water inlet device is the one which has a high DOS, availability change, merit factor, energy delivery, and average availability ratio. Furthermore, it has a low entropy ratio and a low internal entropy generation. The results of this testing indicated that using a four-port manifold in which the port diameter increases gradually from small at the bottom to large at the top is a workable solution to enhance stratification. Also, the four-port manifold has the highest degree of stratification, and a high change rate for the temperature of the top tank layers and responded earlier in the day than the traditional design for most of the experimental tests. This means the four-port manifold has the ability to enhance stratification. Furthermore, we found that it is difficult to use entropy ratios to determine the ability of hot water inlet devices to enhance stratification, because the entropy difference values were too small. Moreover, the normalized entropy ratio and internal entropy generation results were both greater than one, which are an unrealistic value. Due to this issue we cannot recognize these two parameters in our evaluations.

Description

Thermal stratification in a solar hot water tank has the effect of decreasing the amount of auxiliary energy consumption so that the energy storage efficiency for the whole system may be increased [2]. If the cold water is allowed to be mixed with the hot water in the solar domestic hot water tank, the supplied temperature to the load is lowered, and the quality of energy is degraded. However, the proper design for enhancing the thermal stratification inside a side-arm storage tank using PV has not yet been determined. Most of the factors that cause mixing inside solar domestic hot water tanks are known, but research is required both to clarify the important issues and develop devices that enhance stratification [21]. Furthermore, thermal energy storage is one of the main components in a solar domestic hot water (SDHW) system. Designing an effective thermal storage tank for these systems is essential for meeting the heating demands when the supply and the exhaust of energy cannot be kept in balance [13]. For this reason, thermal energy storage has become an important area of research toward enhancing the performance of SDHW systems.

Keywords

Storage Tank, Solar Domestic Hot Water System, Thermal Stratification and Photovoltaic

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