Article Per Year (5 Year)
p-Index From 2020 - 2025
0.23
P-Index
This Author published in this journals
All Journal Jurnal Energi dan Lingkungan (Enerlink) International Journal of Renewable Energy Development
Abdul Wahid, La Ode Muhammad
Unknown Affiliation
Control & Systems Engineering Earth & Planetary Sciences Electrical & Electronics Engineering Energy Engineering

Published : 2 Documents Claim Missing Document
Claim Missing Document
Check
Articles

Found 2 Documents
Search

 1 
DAMPAK FEED-IN TARIFF ENERGI TERBARUKAN TERHADAP TARIF LISTRIK NASIONAL Abdul Wahid, La Ode Muhammad
Jurnal Energi dan Lingkungan (Enerlink) Vol 11, No 1 (2015)
Publisher : Badan Pengkajian dan Penerapan Teknologi

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (2557.093 KB) | DOI: 10.29122/elk.v11i1.1587

Abstract

Pemanfaatan energi terbarukan sangat terbatas dengan bauran energi terbarukan hanya 4,76%terhadap total bauran energi nasional. Hal ini disebabkan karena harga jual listrik pembangkit energiterbarukan pada umumnya lebih mahal dibanding pembangkit energi fosil. Untuk mendorongpemanfaatan energi terbarukan,Pemerintah telah menetapkan berbagai regulasi tentang harga juallistrik dari pembangkit listrik energi terbarukanyang wajib dibeli oleh PT PLN, seperti regulasi PLTP,PLTA, PLTS, PLTSampah, dan PLTBiomassa. Namun, hasil analisis menunjukkan bahwa beberapaharga jual listrik pembangkit energi terbarukan tersebut lebih mahal dari rata-rata biaya operasipembangkit listrik PLN yang pada tahun 2014 mencapai Rp. 1.297/kWh, bahkan ada yang lebih mahaldari biaya operasi PLTD. Hal ini berdampak terhadap kenaikan biaya pembelian listrik PLN, padahalharga jual listrik masih ada yang ditetapkan dengan harga subsidi. Kondisi ini akan menyebabkannaiknya subsidi listrik atau naiknya Tarif Dasar Listrik. Kenaikan Tarif Dasar Listrik akan berdampakterhadap pelanggan listrik rumah tangga. Hasil analisis dari data Susenas BPS menunjukkan bahwarumah tangga dengan pengeluaran maksimum 5 juta rupiah per bulan merupakan rumah tangga yangpaling terkena dampak atas kenaikan Tarif Dasar Listrik karena merupakan 91,33% terhadap totalpelanggan rumah tangga.Kata kunci: fit energi terbarukan dan tarif listrik
Renewable energy in sustainable cities: Challenges and opportunities by the case study of Nusantara Capital City (IKN) Yudiartono, Yudiartono; Santosa, Joko; Fitriana, Ira; Wijaya, Prima Trie; Rahardjo, Irawan; Abdul Wahid, La Ode Muhammad; Siregar, Erwin; Hesty, Nurry Widya; Fithri, Silvy Rahmah; Sugiyono, Agus
International Journal of Renewable Energy Development Vol 13, No 6 (2024): November 2024
Publisher : Center of Biomass & Renewable Energy (CBIORE)

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.61435/ijred.2024.60390

Abstract

This study explores strategies for optimizing energy consumption in Indonesia's New Capital City (IKN) to achieve net zero emissions by 2045, focusing on energy efficiency, sustainable mobility, and renewable energy through the Low Emissions Analysis Platform (LEAP) model. Sustainable cars, such as renewable-energy-powered electric and green hydrogen-powered vehicles, can reduce energy consumption by 43% in 2045 and 33% in 2060, respectively, compared to BAU. GHG emissions per capita will drop 70% in 2045 and 63% in 2060. In NZE scenario, IKN can reach 100% green energy by 2045 with a 4.4 GW solar power plant, a 0.92 GWh BESS, and a full load hour capability of 4 hours. By 2045, 1.1 GW of hydropower and 143 MW of wind power are expected to be utilized. In 2060, hydropower will be 2.8 GW, wind power will be 184 MW, and solar power will be 8 GW with 1.6 GWh of BESS. Lack of legislation, technical expertise, high prices, inadequate grid infrastructure, and renewables shortfalls restrict Indonesia's BESS. Solar installation criteria, subsidies, and off-grid project incentives can all help ease BESS use. Forecasts predict 0.53 GW of rooftop solar PV capacity by 2045 and 3.35 GW by 2060. Net metering and solar tariffs boost rooftop solar system profitability. One ton of green hydrogen production requires 55.7 MWh from a solar power plant. Solar power plant capacity will rise to 0.49 GW by 2045, producing 19,359 tons of green hydrogen, and almost quintuple to 89,594 tons by 2060. Hydrogen generation, storage, transit, and distribution require specific infrastructure due to high capital costs and a lack of networks, yet interest in them is growing.
Co-Authors Agus Sugiyono Erwin Siregar Fithri, Silvy Rahmah fitriana, ira Hesty, Nurry Widya Joko Santosa, Joko Rahardjo, Irawan Wijaya, Prima Trie yudiartono, yudiartono