This study aims to determine the comparison of two electrical energy produced by the Minihidro Power (PLTMH) at different
heights and water discharge. After all the systems that support the construction of the mini-hydro have been designed and
connected to each other to form the expected mini-hydro system, the next step is the mini-hydro work testing phase. As for the
implementation using the experimental method by operating a mini-hydropower plant with variations in changing the height
and water discharge. This research was conducted to determine the current and voltage produced by observing the current and
input voltage and current and output voltage of the inverter circuit. The test is carried out using ammeters and voltmeters, then
the measurement results are entered in a table. This study obtained data V and me to calculate the electric power generated
(P). The analysis was done descriptively by comparing the data obtained to observe the effect of water height (h) and water
discharge (Q) on electric power (P). From the experimental results, the greater the price of h and Q, the greater the P
produced. So from this experiment, we can be implemented in a PLTMH builder by knowing the maximum water level and
discharge from a water source. From the results of these experiments it can be said the higher the water to the generator, the
greater the electrical energy produced. This is in accordance with the potential energy it has. The greater the potential energy of
an object means the greater the electrical energy. From the comparative data of Experiments 1 and 2, it is obtained that the
amount of water debit greatly influences the amount of energy/electricity generated. This is due to the large mass of water that
will hit the turbine so the generator turns faster, resulting in large mechanical energy. So to build a PLTMH, water flow and
altitude must be considered.

Adhau, S. P., Moharil, R. M., & Adhau, P. G.

(2012). Mini-hydro power generation on

existing irrigation projects: Case study of

Indian sites. Renewable and Sustainable

Energy Reviews, 16(7), 4785-4795.

https://doi.org/10.1016/j.rser.2012.03.06

Al Mamun, K. A., Yusuf, M. S., Alam, M. A.,

Ahmed, S., & Nath, A. (2018). Design

And Implementation Of A Micro Hydro

Module For Small Falling Water Source.

In 2018 International Conference on Computer,

Communication, Chemical, Material and

Electronic Engineering (IC4ME2) (pp. 1-4).

IEEE.

Candra Mayana, H. Study Potensi Pembangkit

Listrik Tenaga Mikro Hidro Di Nagari

Sibarambang Kecamatan X Koto Di Atas

Kabupaten Solok Sumatera Barat. In

Seminar Nasional Teknik Elektro (SNTE)

(pp. 1-10). Politeknik Negeri Padang.

Celikdemir, S., Yildirim, B., & Ozdemir, M. T,.

(2017). Cost Analysis of Mini Hydro

Power Plant Using Bacterial Swarm

Optimization. International Journal of Energy

and Smart Grid, 2(2), 64-81. doi:

23884/IJESG.2017.2.2.05

Flury, K., & Frischknecht, R. (2012). Life cycle

inventories of hydroelectric power

generation. ESU-Services, Fair Consulting in

Sustainability, commissioned by Oko-Institute

eV, 1-51.

Hanafi, J., & Riman, A. (2015). Life cycle

assessment of a mini hydro power plant

in Indonesia: a case study in Karai

river. Procedia Cirp, 29, 444-449. doi:

1016/j.procir.2015.02.160 Jamali, F. (2014). Studi Perencanaan Pembangkit

Listrik Tenaga Minihidro Berbantuan

Program Turbnpro di Desa Sinar Pekayau

Kecamatan Sepauk Kabupaten Sintang.

Jurnal Teknik Elektro Universitas

Tanjungpura, 1(1).

Kadir R. 2010. Perancangan pembangkit listrik

tenaga mikro hidro (PLTM) disungai

marimpa kecamatan pinembani. [Tesis

publis]. Palu (ID): Universitas Tadulako.

Kosjoko, Kosjoko. "Cros Flow as Turbine

Power Plant Minihidro (Pltm) Village to

Self Energy" Infoteknik, vol. 16, no. 2,

, pp. 159-170.

DOI: http://dx.doi.org/10.20527/infote

k.v16i2.200

Kurniawan A, Gunawan AI, Maryono A, Ikhsan

A, Susandi A, Sudaryanto A, Adriawan C,

Boediyono C, Mamesah C, Kusdiana D et

al.. 2009. Pedoman Studi Kelayakan Sipil,

Buku 2B. Jakarta (ID) : Direktorat

Jenderal Listrik dan Pemanfaatan Energi,

Departemen ESDM.

Prasetyo, T. E., & Pane, Z. (2013). Studi

Proteksi Pada Pembangkit Listrik Tenaga

Minihidro (PLTM) Silau 2 Tonduhan

Kabupaten Simalungun. Singuda

ENSIKOM, 2(3), 113-118.

Rizki, A. A., & Alfi, I. (2019). Rancang Bangun

Mini Mikro Hidro Sebagai Pembangkit

Sederhana Dengan Pemanfaatan Arus Air

Kran wudu Otomatis Menggunakan Metode

Turbin Air Vertical (Doctoral dissertation,

University of Technology Yogyakarta).

Setiawan Wie, D. (2017). Perencanaan Dan

Implementasi Prototipe Pembangkit

Listrik Tenaga Mikro Hidro (PLTMH).

Jurnal Teknik Elektro, 7(01).

Sinaga, B.J. (2009). Perancangan turbin air untuk

sistem pembangkit listrik tenaga mikro

hidro (Studi kasus Desa Way Gison

Kecamatan Sekincau Kabupaten

Lampung Barat). Jurnal Sains dan Inovasi.

(1) : 64-75.

Sipayung, H. P. (2019). Studi Kelayakan

Pembangkit Listrik Tenaga Minihidro

(OLTM) di Sungai Berkail Kecamatan

Bahorok Kabupaten Langkat.

Sugiyono. 2013. Metode Penelitian Pendidikan

Pendekatan Kuantitatif, Kualitatif, dan

R&D. Bandung: Alfabeta.

Sulistiyono, Sugiri A, Eka Y. 2013. Studi potensi

pembangkit listrik tenaga mikrohidro

(PLTM) di Sungai Cikawat Desa Talang

Mulia Kecamatan Padang Cermin

Kabupaten Pesawaran Propinsi Lampung.

Jurnal FEMA. 1(1): 48-54

Sukamta S, Kusmantoro A. 2013. Perencanaan

pembangkit listrik tenaga mikrohidro

(PLTM) Jantur Tabalas Kalimantan

Timur. Jurnal Teknik Elektro. 2(5): 58-63

Syarif, A. (2019). Rancang bangun prototipe

pembangkit listrik tenaga mikro hidro

(pltmh) turbin pelton. Kinetika, 8(2), 1-6.

TAOFEQ, T., ANGGORO, B., &

ARFIANTO, T. (2013). Perancangan

Sistem Kelistrikan Pada Pusat Listrik

Tenaga Minihidro Lapai 2x2000 kW di

Sulawesi Tenggara. REKA ELKOMIKA,

(2)

Warsito, S., Syakur, A., & Nugroho, A. A.

(2005). Studi Awal Perencanaan sistem

Mekanikal dan Kelistrikan Pembangkit

Listrik Tenaga Mini-Hidro. In Seminar

Teknik Ketenagalistrikan, Teknik Elektro

Fakultas Teknik Universitas Diponegoro,

Semarang