Investigation of steam generation performance on conical cavity receiver by different geometric concentration ratios for fresnel lens solar concentrator

Authors

DOI:

https://doi.org/10.15587/1729-4061.2020.209778

Keywords:

steam performance, Fresnel lens, solar concentrator, conical cavity, receiver, temperature, direct normal irradiation, geometric concentration ratio, latent heat, efficiency

Abstract

The paper discusses the comparison of the performance of steam generators in large and small receivers, using a Fresnel lens concentrator.

The goal is to get the best value from the efficiency of a steam generator between large and small receivers, with the following task details:

a) design a conical cavity receiver that has the most efficient geometric concentration ratio;

b) compare the thermal efficiency of conical cavity receivers that have different geometric concentration ratios;

c) analyze the potential of the steam energy from the conical cavity receiver produced by the PMMA Fresnel lens concentrator based on the amount of average radiation directly at the study site.

The study uses an experimental field research method, which is conducted outdoors. This research was conducted in the energy conversion laboratory, Universitas Brawijaya (Latitude: 7.9553° S and Longitude: 112.6145° W), in September 2019. The PMMA Fresnel lens is used for the solar thermal concentrators. The two receivers with a conical cavity that were compared were made of copper with a volume of 2 litres and 0.25 litres, respectively. They are coated with a glass wool insulator with a thickness of 10 mm. Direct Normal Irradiance (Ib) is measured by a solar power meter. The cup anemometer is used to measure wind speed (vw) around the receiver. Digi-Sense 12 Channel Scanning Benchtop Thermometer connected to the laptop is used to measure temperature. The positions of the four K-type thermocouples are as follows:

1) ambient temperature (Ta);

2) focal point temperature (Tf);

3) receiver wall temperature (Tr);

4) steam/water temperature (Tw).

A pressure gauge to measure the pressure of the steam that goes to the measuring cup was used. After saturation pressure (Psat) has been reached, it will be known from the condensation process through the copper coil, which functions as a condenser.

From the results of the study, the large receivers have specifications CRg=8 and a volume of 2 litres of water. Whereas, the small receiver is CRg=30 and 0.25 L. The large receivers can produce steam latent heat energy Qs=1.37 MJ per cycle with useful efficiency (utilization efficiency) ηTh=31.81 %. Whereas the small receiver can produce steam energy, Qs=579.17 kJ per cycle with useful efficiency, ηTh=33.31 %. Hence, from the two types of conical cavity receivers, small receivers have that higher effectiveness than large ones can be recommended

Author Biographies

Asrori Asrori, Brawijaya University Jl. Mayjend Haryono, 167, Malang, Indonesia, 65145 State Polytechnic of Malang Jl. Soekarno-Hatta, 9, Malang, Indonesia, 65141

Doctoral Student

Department of Mechanical Engineering

Lecturer

Department of Mechanical Engineering

Sudjito Suparman, Brawijaya University Jl. Mayjend Haryono, 167, Malang, Indonesia, 65145

PhD, Professor

Department of Mechanical Engineering

Slamet Wahyudi, Brawijaya University Jl. Mayjend Haryono, 167, Malang, Indonesia, 65145

Doctor of Mechanical Engineering, Associate Professor

Department of Mechanical Engineering

Denny Widhiyanuriyawan, Brawijaya University Jl. Mayjend Haryono, 167, Malang, Indonesia, 65145

Doctor of Mechanical Engineering, Associate Professor

Department of Mechanical Engineering

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Published

2020-08-31

How to Cite

Asrori, A., Suparman, S., Wahyudi, S., & Widhiyanuriyawan, D. (2020). Investigation of steam generation performance on conical cavity receiver by different geometric concentration ratios for fresnel lens solar concentrator. Eastern-European Journal of Enterprise Technologies, 4(8 (106), 6–14. https://doi.org/10.15587/1729-4061.2020.209778

Issue

Vol. 4 No. 8 (106) (2020): Energy-saving technologies and equipment

Section

Energy-saving technologies and equipment

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Copyright (c) 2020 Asrori Asrori, Sudjito Suparman, Slamet Wahyudi, Denny Widhiyanuriyawan

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