Development and performance evaluation of solar heating system for biogas production process

The breakdown of organic waste, through anaerobic digestion, is a temperature dependent pro-cess. Attaining the temperature required for this process, under normal conditions, is a chal-lenging task. Hence, the development of an effective heating system is necessary. In this paper, a solar heater's computational fluid dynamics (CFD) model, with water as working fluid, is pre-pared to estimate the temperatures of the absorber plate and that of the water available at the outlet. The validations of the numerical results were done by conducting experimental trials and a fair agreement between them was observed. For the examined solar collector, with outlet tem-perature of 61 degrees C, the maximum thermal efficiency was estimated as 71%. The effects of operating parameters (like transmissivity coefficient, ambient temperature, wind speed, inlet water tem-perature and sun's insolation), were explored. It was predicted that 30-60 degrees C tank water tem-perature can be attained at flow rates of 0.00833, 0.0167, and 0.021 kg/s. The bent-tube Flat Plate Colector (FPC) model, proposed in the present work, increases the residence time of water in the collector. It also increases the outlet temperature. Hence, the developed FPC model may be considered as an alternative solution for growing thermophilic bacteria during the anaerobic digestion in biogas production.

Automated summary

A computational fluid dynamics model of a solar heater is developed in this study, and its numerical results are validated by experimental trials. The study finds that different water temperatures can be achieved by adjusting the operating parameters.