Temperature Effect on Densification of Banana Peels Briquette (ICCSE 2018) PDF

Summary

This study analyzes the effects of varying temperatures during carbonization on banana peel briquette production. The research investigates how temperature impacts densification and the resulting properties of the briquettes, including compressive strength and calorific value. The results suggest banana peels are a promising biofuel source.

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Materials Today: Proceedings 19 (2019) 1403–1407 www.materialstoday.com/proceedings

ICCSE 2018

Temperature Effect on Densification of Banana Peels Briquette
Nona Merry M. Mitana*, Muhammad Fakhrur Radzi Sa’adonb
a
Department of Chemistry, Faculty of Science and Computer, Universitas Pertamina, 12220 Kebayoran Lama, Jakarta, Indonesia.
b
Department of Thermal-Fluids, Faculty of Mechanical Engineering, Universiti Teknikal Malaysia Melaka, 76100 Durian Tunggal, Melaka,
Malaysia.

Abstract

As a lignocellulose source, banana peel has possibility to convert to be a solid biofuel. This current research applied Tanduk
banana peels waste for main material of briquette. The aim of this research is to observe the effect of temperature during
carbonization of banana peels and its impact on densification of banana peel to produce a high quality of briquette. Carbonization
temperature of banana peels was carried at three different temperatures of 270 (C270), 370 (C370) and 470 (C470) oC. The
densification of carbonized banana peel was 40.0 tons. Furthermore, densification also performed on the non-carbonization of
banana peel (NC) on order to compare the results without presence of any binder materials. Initial results involved proximate
analysis to fulfill the briquette standard requirement and compressive analysis to investigate the strength of briquette. The
proximate analysis shown that moisture content of carbonized briquettes were about 5.00 to 6.06 %, ash content were about 20.59
to 30.03 %, volatile matter were about 61.91 to 70.15 % and fixed carbon were about 2.00 to 3.80 % respectively. These findings
quite different with non-carbonized briquette. In addition, the compressive analysis obtained that the non-carbonized (NC)
briquette produce the highest compressive load limit. Compressive analysis is important to know the ability of briquette to resist
the load for logistics purposes. The preliminary results support the idea that banana peels waste are potential to be process as a
briquette of solid biofuel.

© 2019 Elsevier Ltd. All rights reserved.
Selection and peer-review under responsibility of the scientific committee of the International Conference on Chemical Sciences and
Engineering: Advance and New Materials, ICCSE 2018.

Keywords: Banana peel; briquete; densification; lignocellulose; temperature effect

* Corresponding author. Tel.: +62-21-290-44308.
E-mail address: [email protected]

2214-7853 © 2019 Elsevier Ltd. All rights reserved.
Selection and peer-review under responsibility of the scientific committee of the International Conference on Chemical Sciences and
Engineering: Advance and New Materials, ICCSE 2018.
1404 N.M.M. Mitan and M.F.R. Sa’adon / Materials Today: Proceedings 19 (2019) 1403–1407

1. Introduction

Dependency of the world on fossil fuel is shifting to bio-energy since depletion of fossil fuel. Agriculture waste is
one kind of bio-energy source. Some examples of agricultural waste that are commonly used as energy sources or
other applications namely coconut shell, water hyacinth and rice husk. Agriculture waste rich of valuable chemicals
such cellulose, hemicellulose and lignin. Instead of renewable energy, agriculture waste also possible to be treated
into adsorbent, fertilizer, composite and other products.
Banana is a member of Musaceae family and well known tropical plant in the world. From the whole fruit,
banana peels portion is 18-33 %. Banana peels from three varieties (Pachabale, Yelakkibale and Nendranbale)
consist of protein, ether extractives and ash as follows 4.6-7.7 %, 5.13-11.26% and 8.9-12.96% respectively.
Recent evidence suggests that banana peel is an efficient and low-cost adsorbent for fluoride treatment in water.
Banana peel can remove 86.5 % of fluoride in contaminated water. The research on fluoride treatment was also
performed by Bhaumik and Mondal. They applied response surface modelling approach to optimize the adsorption
method of fluoride in water by banana peel dust. The highest adsorption capacity of fluoride by banana peel dust was
39.5 mg/g. In other research, the potential of banana peel as starch source was explored by Hadisoewignyo et al.
They found that banana peel starch has lower temperature of gelatinization than starch from cassava.
Wilaipon applied banana peels for briquetting. The briquette produced under pressure from 3 to 11 MPa in the
presence of molasses as a binder. The impact resistance and compressive strength tests was passed by briquettes that
applied pressure over 7 MPa. These findings support the idea to utilize the banana peel as bioenergy source in
briquette form. Sellin et al. attempted to reuse the pseudostem and banana leaves to generate briquette for alternative
fuel. The pseudostem and leaves briquettes released high heating value of 13.70 and 17.10 MJ/kg respectively.
Moreover, banana peel also potential for biomethane source. Pisutpaisal et al. observed the anaerobic fermentation
of banana peel under mesophilic condition with batch reactor. The maximum production rate of methane was 5.31
mL/hr at 7.5 % of total solid.
In recent years, there has been an increasing interest in reutilizing of banana peels waste. However, study about
briquetting of banana peel still less in particular of temperature effect of carbonization. Therefore, the objectives of
the current research are to determine the temperature effects on densification of banana peels into briquette.

2. Methodology

2.1. Materials and preparation of banana peel briquette

Banana peel from Tanduk banana waste (Musa paradisiaca fa. corniculate) were collected form home industry of
banana chips manufacture around Batu Pahat, Johor and Merlimau, Melaka, Malaysia. Prior to process the banana
peels to briquette, the peels were cleaned from dirt and dried at 100 oC for 24 hours to prevent the peels from
fungus. After drying, the peels were reduced the size and milled into 0.75 mm by crusher machine and centrifugal
milling machine (Retsch ZM 200).
Carbonization of banana peel was performed after milling at three different temperatures namely, 270, 370 and
470 oC respectively by furnace (Carbolite Type 201) with heating rate 10 oC/min for 60 min. The 10 g of carbonized
banana peels were densified at 40 ton for every type of banana peels used a mold and hydraulic press (Hsin-Chi HL
200). Dimension of mold for densification has 35 mm of inner diameter and 10 mm of thickness.

2.2. Analysis of banana peels briquettes

Analysis of banana peel briquettes involved the proximate analysis, calorific value and compressive test.
Proximate analysis was conducted based on American Society for Testing Materials (ASTM) D 3173-03 for
moisture content, D 3174-02 for ash content and D 3175-02 for volatile matter respectively. Furthermore, the
theoretical calorific valued is determined based on developed formula by Erol et al. as follows:

𝑁𝐻𝑉 = −116 − 1.33[𝐴𝑠ℎ] − 0.005[𝑉𝑀] + 1.92 [𝑉𝑀 + 𝐴𝑠ℎ] − 0.0227[𝑉𝑀 𝑥 𝐴𝑠ℎ] − 0.0122[𝑉𝑀]
+ 0.0299[𝐴𝑠ℎ] + 6133[𝑂𝑀] − 0.82[𝐴𝑠ℎ] (1)
 N.M.M. Mitan and M.F.R. Sa’adon / Materials Today: Proceedings 19 (2019) 1403–1407 1405

The compressive test was performed by Universal Testing Machine (Instron 5583) to assess the behavior of
briquette under load.

3. Results and discussion

The densification of banana peels succeeded to form the briquettes as shown in Fig. 1. The quality of briquettes
was analyzed by proximate analysis as a standard for coal products. The moisture content reflects to the quality of
briquette. The quality of briquette will decrease in line with increasing of moisture content. As shown in Fig. 2, the
moisture content almost no significant differences between four briquettes. The moisture content lies from 5.00 to
7.06 % for all briquettes. The NC briquette has 7.06 % of moisture content. This is due to original composition in
NC briquette such as cellulose, hemicellulose and lignin. In carbonized briquettes, the C270 gives the lowest
moisture content (5.00 %).

Fig. 1. Non-carbonized (NC) and carbonized banana peels briquettes at 470 oC (C470)

Ash content is origin mater left after burning process of sample. The lowest ash content was produced from NC
briquette (8.16 %) and the highest ash content was found in C470 from the highest temperature of carbonized
banana peel.
Volatile matter is described the percentage of decomposition of compound in gaseous products that can evaporate
at certain temperature and pressure. The high volatile matter lead to smoke formation. The highest volatile matter
was found in NC sample (72.47 %). In case of carbonized banana peels, the carbon form decreased the evolatile
matter.
Fixed carbon is summing up of moisture, ash and volatile matter percentages and describe the carbon content
remain after volatile matter is released. The NC briquette has the highest fixed carbon (12.31 %). The highest
temperature (C470) reveals the lowest of fixed carbon due to the volatile matter content is less.

Fig. 2. Proximate analysis of banana peel briquette at various temperatures
1406 N.M.M. Mitan and M.F.R. Sa’adon / Materials Today: Proceedings 19 (2019) 1403–1407

The calorific value of briquette is indicator of potential energy inside of briquette. As an important parameter of
fuel, all carbonized banana peels briquettes gave higher calorific value than non-carbonized banana peels briquettes.
The highest of theoretical calorific values was obtained from C470 namely 47.13 MJ/kg. Increasing the temperature
will increase the theoretical calorific value as well as shown in Fig. 3.

Fig. 3. Theoretical calorific value of banana peels briquettes at various temperatures

Figure 4 shows the compressive test of banana peels briquette. The non-carbonized briquette can withstand the
load of 18.03 kN. Increasing the temperature of carbonized banana peels lead to fragile of briquette. As appear in
Fig. 4., the capability to withstand the load sharply declined from NC to C470 briquettes. The compressive analysis
results is useful for logistics purposes.

Fig. 4. Compressive test of non-carbonized (NC) and carbonized banana peels briquettes (C470)
 N.M.M. Mitan and M.F.R. Sa’adon / Materials Today: Proceedings 19 (2019) 1403–1407 1407

4. Conclusion

Investigation on banana peel waste as a candidate of solid biofuel was carried out by carbonization and
densification process. The carbonization was performed at three different temperatures of 270, 370 and 470 oC. The
highest temperature of carbonization (470 oC) of banana peels yields highest theoretical calorific value. Increasing
of temperature of carbonized banana peel decreased the stability of briquette to withstand the load.

Acknowledgements

This research was supported by Faculty of Mechanical Engineering, Universiti Teknikal Malaysia Melaka,
Malaysia. The authors would like to thank you to all technician staffs in Faculty of Mechanical Engineering who
provided assistance during this research. This results partially has been submitted as a Final Year Project of
Bachelor Degree to Universiti Teknikal Malaysia Melaka.

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