Pengaruh Lifting Strakes Terhadap Performance dan Ekonomis Pada Kapal Cepat (Planning hull)


 

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The Spirit of Society Journal 
Volume 5, Number 1 
September 2021 

Tourist Boat Electrification 
 

Hendro Agus Widodo1, Joesianto Eko Poetro2, M. Basuki Rahmat3, Purwidi Asri5,  
Edy Prasetya H6, Catur Rahmat H7,  

Marine Electrical Engineering, Shipbuilding Institute of Polytechnic Surabaya, Indonesia 
mbasuki.rahmat@ppns.ac.id3* 

 
Abstract; As a city crossed by rivers, Surabaya has the potential for attractive water 
tourism. Kalimas is one of them. Kalimas is a river that divides Surabaya. Kali Mas is a 
tributary of the Brantas River. This main river flows from Mojokerto as its headwaters, then 
flows to the northeast, empties into Surabaya, and ends in the Madura Strait. Muara Kali 
Mas has been Surabaya's traditional port for centuries. This port became the gateway to the 
capital of the Majapahit Kingdom (in Trowulan), and became part of the Surabaya people's 
battle against the allies before November 10, 1945. In various countries, river tourism has 
developed. Not only for city residents, but has become part of the State's tourism. One 
example is in Italy, namely tracing the river canals in Venice in Italy. Everything is described 
so well that everyone who comes wants to try it. Experiences and interesting photo 
documentation make river tourism an opportunity to develop. River tourism can be a 
potential alternative for Surabaya residents. Become a means of recreation or further 
developed into a tourist vehicle of national and even international standards. An important 
means of water tourism is a boat. Tour boats were developed to support the success of this 
tour. This article discusses the electrical installation for tourist boats that will be used on the 
Kali Mas River. Its power source is taken from diesel engines and also from solar panels that 
are capable of generating electricity. 

Keywords: Tourist Boat, Electricity, River 
 
INTRODUCTION 

Surabaya as a city of heroes has many historical locations. Some of them are related or 
located in water areas (city’s rivers area). One of the most historical and importance river in Surabaya 
is Kali Mas, which is a part of the Brantas river. The river is also a borderline between Surabaya City 
and Sidoarjo Regency and Gresik Regency. In the past and even centuries ago, Kali Mas as the 
wheel of economic and trade cycles even in historical records at that time became the gateway to the 
capital of the Majapahit Kingdom in Trowulan Mojokerto, as well as witnessing the history of the 
heroic battle between Raden Wijaya, the founder of the Majapahit empire and the troops. Tartars 
during the Mongol rule in the 13th century. During the Dutch colonial period, Kali Mas became one of 
the most vital means of water transportation, several modes of water transportation, both canoes, 
boats transporting commodities and fish caught by fishermen from the port of Tanjung Perak to the 
interior of the city, from Kembang Jepun to the Chinatown area to other areas. Kayun once operated 
a suspension bridge that could be lifted when a commodity ship passed into this area. Kalimas River 
is the main priority that is planned to develop river transportation, tourism transportation and goods 
logistics. This is considering the characteristics of the Kali Mas River with a length of about 18 KM, a 
width of between 20-35 meters and a depth of about 50 centimeters to six meters. One of the tourist 
boat models used can be seen in Figure 1. This tourist boat is very simple. Driven by a diesel 
outboard engine. Tour boats are operated during the day. Standard requirements for safety and 
operational feasibility have not been met. Therefore, it is very necessary to make tourist boats 
operated at night with the eligibility requirements and passenger safety a priority. 

mailto:mbasuki.rahmat@ppns.ac.id


 

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September 2021 

 

 

Figure 1. The existing Tourist Boat  
(https://surabaya.liputan6.com/read/4097038/pemkot-surabaya-identifikasi-4-sungai-untuk-

transportasi-air) 
 

METHODOLOGY 

Research activities begin with the preliminary stages, namely literature study, data collection 
of load and electricity demand and analysis of demand data. 

A literature study  

A literature study was conducted to study the latest developments related to solar panel 
technology, battery technology and the utilization of solar power generation systems used as ship 
propulsion. 

Data collection on electricity demand 

At this stage, both qualitative and quantitative data were obtained from a survey conducted with 
the Surabaya State Shipping Polytechnic tourism ship design team. The qualitative data obtained 
include: 

• The ship will be operated on the river in Surabaya (Kalimas River) 
• The ship is only operated during the day 
• Should the ship use the main source of solar panels as a source of energy 
• Passenger capacity 10 people 

From this data, it is known that the load includes Outboard Machines, Lighting Lamps, Decorative 
Lights, Remote Lights, and Sound Systems. 

Calculation and Analysis 

At this stage, calculations and analysis are carried out to get a complete picture of the ship's 
electrical needs, for tourist ships that you want to design and build in the future. 

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ISSN : 2594-4777 (Online) – ISSN : 2597-4742 (Print) 
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Volume 5, Number 1 
September 2021 

RESULTS AND DISCUSSION 

Tourist Boat Specifications 

The designed tourist ship has the following specifications: 

• LoA  : 8.00 m 
• B  : 3.00 m 
• H  : 1.50 m 
• T  : 0.6 m 
• CB  : 0.46 
• Roaming duration: 2 hours (temporary) 
• Maximum speed: 5 knots (~9 km/h) 
• Cruising speed: 4 knots (~8 km/h) 

Figure 2 is the roof design that the plan is to use. The roof of the ship will be given 41 solar 
panels which will be channeled to the battery to be stored and used properly. 

 
Figure 2. Solar Roof 

The design of the roof of the ship is made as if there are additional areas such as two fins on 
the right and left. This area can be tucked under the roof if not needed. The roof is given solar panels 
as much as 2 x 6 cells can be added to increase input. Figure 2, is the specification of Flexible Solar 
Panel used in this study. 

The solar panel used is a flexible Jskye model ST44M 140-FLP; each panel has dimensions 
of 1,435 mm x 540 mm x 15 mm, maximum power voltage (Vmp) 24.2 V, maximum power current 
(Imp) 5.8 A, with maximum output power (WPmax) 140 W. The picture 3, shows the general 
arrangement. For a schematic diagram of the electrical system shown in Figure 4. 



 

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September 2021 

 

Figure 3. General Arrangement for Placement of Batteries and Fresh Water 

 

 

Figure 4. Electrical Schematic Diagram 

Electrical Equipment Needs 

The need for electrical equipment is very necessary for the convenience of passengers. For 
this reason, it is necessary to regulate the electrical loads, in such a way that they meet the technical 
requirements of the ship, including those related to heavy loads (in kg). The need for electrical 
equipment is shown in Table 1 below. 

Table 1. Electrical Equipment 

No Part Weight (kg) Note 

1 Hull 1560 
 

2 Superstructure 800 
 

3 Outboard Engine  180 2 unit 

4 Batteries  480 8 unit; 20.6X9.4X8.8 In 

5 Passenger & Crews 750 10 person 

6 Solar Panel 200WP 1.5 40 unit 

 



 

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September 2021 

From the analysis carried out, the following data were obtained. With parameter LCG = 3.6 m; 
TCG = 0 M; and KG = 0.55m. The Outboard Machine includes: 

• Lighting 
• Decorative lights 
• Remote light 
• Sound System (communication tools, navigation lights, AC power balance). 

To calculate the load, the following equation is provided. 

PT = P x t ………………………………………………………………..…………………………….(1) 

PT = V x C …………………………………………………………………………  ………………..(2) 

In the equation, PT is the electrical load in a certain time (Wh), P is the wattage of the tool (W), 
t is the operating time (h), V is the rated voltage of the tool (V), and C is the capacity (Ah). The 15% 
correction factor is also important to include in the calculations. Estimated load for each equipment on 
board identified in Table 2. 

Table 2. Electric Load   

No KOMPONEN 
DAYA 

(WATT) 
TEGANGAN 

(V) 
QUANTITY 

(Unit) 
TOTAL BEBAN 

(WATT) 

1 Lampu Penerangan 10 12 4 40 
2 Lampu Hias 10 12 10 100 
3 Lampu jauh 30 220 2 60 
4 Sound System 50 12 1 50 

5 Motor Listrik Penggerak 5000 48 2 10000 

        Total 10250 
 

Electrical load balance (Power Balance) is a balance between the load and the power plant. 
Because not all the equipment on the ship is fully operational. The boat's electrical load is very 
important under certain conditions, such as when the ship is docked, sailing, and in maximum 
conditions. Based on the results of table 5.2, the maximum load conditions are: 

10.25 kW x 2 hours of cruising x 1.15 (correction factor) = 23.5 kWh. 

Batteries are used to store electricity generated by photovoltaic panels. Serves to supply ship 
equipment. The battery system consists of several batteries connected in series and/or parallel. The 
total voltage of the battery packs connected in series will be the sum of each battery pack voltage. 
While the total capacity of parallel connected batteries (Ah) provided will be the sum of the respective 
battery pack capacities. Batteries can be combined with multiple battery connections to achieve the 
required voltage or capacity, like 2S2P meaning that 2 batteries are connected in parallel then 
connected to another 2 batteries connected in parallel through a series connection. The battery type 
is shown in the table 3. 

Based on the calculation of the electrical load, a maximum energy of 23.5 kWh is required for 
the remaining cruising time (2 hours). To achieve the required power, it is necessary to consider the 
efficiency and Depth of Discharge (about 80%) of the battery system. The required voltage is 48 V, 
according to the voltage of the DC motor and bilge pump. Table 4, shows the calculations that 
determine the battery system, which consists of 4 battery banks (parallel) with each bank consisting of 
4 series of connected battery packs, to achieve load requirements of 48 V and 31 kWh. 



 

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September 2021 

Table 3. The battery type 

Kapasitas Normal 200 Ah 

Nominal Tegangan 12,8 V. 

Bobot 26 kg 

Dimensi 500 x 235 x 225 mm 

Pelepasan Standar (Vco, Id) 8 V, 50 A 

Biaya Standar (Vc) 14.6 V. 

Resistensi internal DC 50 mΩ 

 

Table 4. Battery System Calculation 

Properti Nilai Satuan 
Muatan maksimum 23.5 kWh 
Daya (Efisiensi 10%) 25.8 kWh 
Total Daya (DoD) 31 kWh 
Voltase yang 
Dibutuhkan 

48 Volt 

n Seri 4 pcs 
n Paralel 4 pcs 
Kapasitas baterai 800 ah 
  38.400 Wh 

Kapasitas total 38,4 kWh 

Baterai Dibutuhkan 16 unit 
  416 kg 
Berat Sistem 00.04 ton 

 

Photovoltaic Power Generation System 

To measure the potential of photovoltaic power plants, information on the available space for 
the arrangement of solar arrays on the ship's roof is needed. The flexible solar module used is Skye 
model ST44M 140-FLP, which has dimensions of 1,435 mm x 540 mm x 15 mm, maximum power 
voltage (Vmp) 24.2 V, maximum power current (Imp) 5.8 A, with maximum output power (WPmax) 
140 W. Based on the design of the ship and the available space, the solar modules that are possible 
to be installed on the roof are 40 units, with a series configuration. 

The energy output of the photovoltaic array can be estimated at standard radiation using the 
following equation: 

WN = WPmax x np ………………………………………………………………………………...(3) 

 



 

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September 2021 

WPmax is the maximum peak wattage the panel produces and np is the number of panels 
installed. To produce 40x140=5.6 kWPmax. The average annual electrical energy of the photovoltaic 
array can be estimated by the following equation (Saputra, et al., 2019). 

PDC = Qm x WN x K1 x K2 x K3 x K4 

Where: 

• PDC is photovoltaic energy (kWh/year) 

• WN is the photovoltaic array energy output at standard radiation (kWPmax) 

• Qm is the average annual flux of solar radiation; in this paper we consider a global 
horizontal irradiation of 1500 kWh/m2/year. 

• K1 is the coefficient for temperature effect compensation. The operating temperature 
increases when the solar panel array is placed under the Sun. When the operating 
temperature rises, the power output drops (due to the characteristics of the panel 
material). Our estimate is K1 0.9. 

• K2 is the coefficient for the stain and wear compensation coefficient in the circuit. Our 
estimate is K2 0.9. 

• K3 is the coefficient of energy loss in the DC circuit. Solar panel systems generally have 
several wires to connect to each module, and that number of connections creates some 
constraints in the flow of electricity, which reduces the total power output of the system. 
Our estimate of K3 0.95. 

• K4 is the energy loss coefficient in the DC-DC converter, this tool is used to convert the 
solar panel voltage to a battery that will be used by ship equipment. Our estimate is K4 
0.95. 

The table 5 shows the required photovoltaic system. 

Table 5. Photovoltaic system. 

Properti Nilai Satuan 

Total Panel Surya 40 unit 

Output Daya Tahunan 6.14 MWh 

Output Daya Harian 16.8 kWh 

 

Based on the calculations in table 3, the Skye ST 44 M 140-FLP solar array will be able to 
produce electricity of 6.14 MWh per year, and around 16.8 kWh per day. 

CONCLUSION 

1. The need for machinery and electrical equipment on a tour boat with a capacity of 10 people that 
can meet the needs on the ship is 10.5 kW. 

2. It takes more than 40 units of solar panels to meet the power balance requirements of the ship's 
daily maximum power requirements. 

3. The number of batteries required is 16 units. To meet maximum power requirements for 2 hours of 
roaming time 

 



 

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REFERENCES 

Iradiratu D.P.K, Yan Dewantara B., (2020). Perhitungan Kebutuhan Daya Listrik untuk Penggerak 
Perahu Nelayan Bertenaga Surya. Jurnal Cyclotron Volume 3 Nomor 1.pp.18-21 

K. J. Lee, D. S. Shin, J. P. Lee, D. W. Yoo, H. K. Choi and H. J. Kim, "Hybrid Photovoltaic/Diesel 
Green Ship Operating in Standalone and Grid-Connected Mode in South Korea - Experimental 
investigation," in IEEE Vehicle Power and Propulsion Conference, Seoul, 2012. 

Saputra, I Wayan. dkk. (2019). Desain Konsep Solar Energy Assisted Water Bus sebagai Sarana 
Transportasi Rute Marunda-Muara Baru, Jakarta, Jurnal Teknik Mesin ITS, Vol 8 No1.ppE80-
E85 

Shi, J., Lee, W.-J., Liu, Y., Yang, Y., & Wang, P. (2012). Forecasting Power Output of Photovoltaic 
Systems Based on Weather Classification and Support Vector Machines. IEEE Transactions on 
Industry Applications, 48(3), 1064–1069 

Sudiyono, S. and Antoko, B., (2008). Perancangan dan Pembuatan Kapal Wisata dengan Motor 
Generator Listrik Tenaga Surya Sebagai Energi Alternatif Penggerak Propeler. Jurnal Teknik 
Mesin, 10(1), pp.52-62. 

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	INTRODUCTION