Abstract:
Lesotho imported 65% of its electricity from Electricidade de Moçambique (EDM) and Electricity
Supply Commission (ESKOM) in 2019/2020 (Lesotho Electricity Company (LEC), 2020). This is
higher as compared to 59% in 2018/2019 ( Lesotho Electricity and Water Authority (LEWA), 2019).
This shows that there is an increasing demand, but stagnant generation capacity hence the ne e d for
the security for the supply of electricity in Lesotho. Studies have shown that the interconnection of
Solar Photovoltaic (PV) systems to the grid can reduce electricity imports amongst others. The
objective of my study is to design optimum grid-connected solar PV systems for residential,
commercial, industrial and institutional purposes; predict the system field performance and d o a
cost-benefit analysis on net metering.
Optimal PV system is designed using the Typical Meteorological Year data closest to Maseru. PV power
and inverter power outputs are calculated for each hour of the given typical year. The different load
profiles from the utility are also used. Net metering policy options guidelines are designed such that PV
electricity is sold to the grid at the utility retail price with no PV capacity cap for net metered systems. The
benefits from net metered PV systems are calculated. These are from surplus sales, avoided energy savings
and peak shaving in the billing period of 12 months.
The results show that with the current electricity tariffs, the PV system that gives the net electricity
payments of zero at the end of the billing period for commercial and industrial customers results in
negative NPV values which indicate that the system is not acceptable. On the contrary, the net-metered
residential PV system offers the profitability index of 2.7643 at the discount rate of three percent (3%)
which is very attractive for investment on the customer‟s perspective. The internal rate of return of the
project is thirteen percent (13%). Based on these results, it is concluded that with the current tariff
settings for residential customers, only the residential PV net metering is technically and economically
viable. As for the commercial and industrial activities, PV net metering is technologically viable
but not economically viable.
The changes in some variables such as dropping of solar PV systems‟ capital and the increase in
energy charges to $0.0423 and $0.039 for commercial and industrial customers respectively, can make
the systems acceptable. The reasonable Net Present Value (NPV) values are likely to increase the
adoption rate of electricity net metering. H o w e v e r , to attract more investment into the net-metering
system, the interest rate of the investment should always be greater than the inflation rate. The larger
12
the range between the two, the more attractive the investment can be.