Flexible demand-side management strategies in solar intermittency mitigation
The acceleration in globalisation has increased international trade and boosted the global economy. With economic developments, countries are producing more goods and services, and with increased purchasing power, consumers can better enjoy these goods and services. With this, an upwards trend in...
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sg-ntu-dr.10356-1572222023-07-07T18:57:50Z Flexible demand-side management strategies in solar intermittency mitigation Tan, Kevin Wei Ming Gooi Hoay Beng School of Electrical and Electronic Engineering Xiong Binyu EHBGOOI@ntu.edu.sg, binyu.xiong@ntu.edu.sg Engineering::Electrical and electronic engineering The acceleration in globalisation has increased international trade and boosted the global economy. With economic developments, countries are producing more goods and services, and with increased purchasing power, consumers can better enjoy these goods and services. With this, an upwards trend in energy demand can be observed globally. Together with global warming, the increase in energy demand, sparked the interest for rapid developments in the renewable energy industry. Solar energy, being one of the more prominent and viable renewable energy sources, has been widely adopted across the world. However, solar energy is extremely reliant on weather and climate conditions. Due to the drop in generated power during bad weather conditions, hybrid energy storage systems need to deliver the energy back to the grid. Demand side management strategies such as peak shaving can be applied to reduce peak energy usage, saving money for consumers. Demand response programs can be used to enforce peak shaving during a fixed period; therefore, they can be applied to further reduce the load demand during periods of solar intermittencies. The effectiveness of peak shaving and demand response programs were evaluated with the aid of HOMER Grid. Both programs were applied to a model configured to replicate a typical commercial building’s load profile. Incentive plans developed to increase the adoption rate of renewable sources were also applied to the model to determine the most economically viable incentive plan. It can be concluded from the simulation results that the larger the size of the alternate energy sources such as generators, solar photovoltaics infrastructure, and batteries, the lower the overall system costs. However, this has a point of diminishing return. As such, with proper considerations taken regarding the size of the alternate energy sources, both the peak shaving and demand response programs can be economically beneficial. With the simulation results, the most economically viable incentive plan could also be determined. Bachelor of Engineering (Electrical and Electronic Engineering) 2022-05-11T12:57:13Z 2022-05-11T12:57:13Z 2022 Final Year Project (FYP) Tan, K. W. M. (2022). Flexible demand-side management strategies in solar intermittency mitigation. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/157222 https://hdl.handle.net/10356/157222 en A1049-211 application/pdf Nanyang Technological University |
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Engineering::Electrical and electronic engineering Tan, Kevin Wei Ming Flexible demand-side management strategies in solar intermittency mitigation |
| description |
The acceleration in globalisation has increased international trade and boosted the global
economy. With economic developments, countries are producing more goods and services, and
with increased purchasing power, consumers can better enjoy these goods and services. With
this, an upwards trend in energy demand can be observed globally. Together with global
warming, the increase in energy demand, sparked the interest for rapid developments in the
renewable energy industry. Solar energy, being one of the more prominent and viable
renewable energy sources, has been widely adopted across the world. However, solar energy
is extremely reliant on weather and climate conditions. Due to the drop in generated power
during bad weather conditions, hybrid energy storage systems need to deliver the energy back
to the grid. Demand side management strategies such as peak shaving can be applied to reduce
peak energy usage, saving money for consumers. Demand response programs can be used to
enforce peak shaving during a fixed period; therefore, they can be applied to further reduce the
load demand during periods of solar intermittencies.
The effectiveness of peak shaving and demand response programs were evaluated with the aid
of HOMER Grid. Both programs were applied to a model configured to replicate a typical
commercial building’s load profile. Incentive plans developed to increase the adoption rate of
renewable sources were also applied to the model to determine the most economically viable
incentive plan.
It can be concluded from the simulation results that the larger the size of the alternate energy
sources such as generators, solar photovoltaics infrastructure, and batteries, the lower the
overall system costs. However, this has a point of diminishing return. As such, with proper
considerations taken regarding the size of the alternate energy sources, both the peak shaving
and demand response programs can be economically beneficial. With the simulation results,
the most economically viable incentive plan could also be determined. |
| author2 |
Gooi Hoay Beng |
| author_facet |
Gooi Hoay Beng Tan, Kevin Wei Ming |
| format |
Final Year Project |
| author |
Tan, Kevin Wei Ming |
| author_sort |
Tan, Kevin Wei Ming |
| title |
Flexible demand-side management strategies in solar intermittency mitigation |
| title_short |
Flexible demand-side management strategies in solar intermittency mitigation |
| title_full |
Flexible demand-side management strategies in solar intermittency mitigation |
| title_fullStr |
Flexible demand-side management strategies in solar intermittency mitigation |
| title_full_unstemmed |
Flexible demand-side management strategies in solar intermittency mitigation |
| title_sort |
flexible demand-side management strategies in solar intermittency mitigation |
| publisher |
Nanyang Technological University |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/157222 |
| _version_ |
1772825471374852096 |