TY  - JOUR
VL  - 12
UR  - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85194398638&doi=10.3390%2fpr12050988&partnerID=40&md5=7d1bc4b50279c95cf224604e9254d625
JF  - Processes
A1  - Sultan, S.M.
A1  - Chih Ping, T.
A1  - Sobayel, K.
A1  - Abdullah, M.Z.
A1  - Sopian, K.
Y1  - 2024///
KW  - Cooling systems; Cost effectiveness; Reflection; Solar panels; Solar power generation
KW  -  Cooler; Cost-efficient; Effectiveness factor; Modified cost and area effectiveness; Module performance; Output power; Photovoltaic module performance; Photovoltaic modules; Reflector; Surface area
KW  -  Solar energy
ID  - scholars19677
TI  - Optimization of the Assessment Method for Photovoltaic Module Enhancers: A Cost-Efficient Economic Approach Developed through Modified Area and Cost Factor
N2  - The advancement of photovoltaic module (PV) enhancer technology shows significant promise due to its rapid growth. Nevertheless, there remains a requirement for ongoing research to refine the evaluation techniques for this technology. In a prior investigation, the concept of the area and cost-effectiveness factor, denoted as (Formula presented.), was introduced to analyze the economic impact of enhancing the PV through techniques such as reflectors or coolers. This metric relates the surface area and manufacturing expenses of a PV enhancer to its capacity for improving the PV output power, aiding in the comparison of different enhancer types. However, this assessment approach is costly, requiring a set of PVs without enhancers to be compared with an equal number of modules fitted with enhancers. This paper introduces a modified version of this metric, termed the modified area and cost-effectiveness factor ((Formula presented.)), along with its minimum value ((Formula presented.)), with the aim of reducing the assessment expenses associated with PV enhancers. This modification hinges on knowing the output power from a single solar cell without an enhancer, as well as from a PV with an enhancer containing a known number of solar cells. Additionally, it relies on data regarding the manufacturing cost of the PV enhancer, the cost of one watt of PV power, and the combined surface area of the PV and its enhancer. The equations for computing the total number of solar cells and the associated costs in addition to the expenses cost are also proposed for (Formula presented.) and (Formula presented.). The results of the present study using (Formula presented.) show that there is a proportional relationship between the percentage of solar cell saving and the number of solar cells. As the solar cells increase, the percentage of solar sell saving increases. The findings reveal that utilizing (Formula presented.) leads to a 48.33 increase in the proportion of solar cells saved compared to the existing method. It can be concluded that the proposed method is cost-efficient and holds promise for adoption by PV enhancer designers and manufacturers. © 2024 by the authors.
IS  - 5
N1  - cited By 0
AV  - none
ER  -