Open-access Physicochemical Properties of a Solid Fuel from Biomass of Elephant Grass Charcoal (Pennisetum purpureum Schum.) and Recyclable PET and HDPE

Abstract

In the search for new solid fuels that can mitigate emissions of greenhouse gases and reduce municipal solid waste, it is proposed to produce a solid fuel from elephant grass charcoal (EGC) and blend it with the following binding recyclable materials, polyethylene terephthalate (PET) and high-density polyethylene (HDPE) with the aim of increasing their mechanical strength. Immediate analysis results indicate that there was an increase in volatile material content from 21.18% to 28.02% and a reduction in fixed carbon from 65.00% to 58.40% with the addition of binding agents. The higher heating value of pure charcoal was 5924.16 kcal/kg and there was no significant alteration by adding HDPE, however, with the addition of PET, there was an average reduction of 4.82%. According to the elemental analysis of charcoal, there were no significant amounts of sulphur, but silicon and potassium oxides were predominantly composed followed by aluminium, titanium, magnesium and iron according to the analysis of ashes. The addition of thermoplastic binders allowed producing pellets and it was found that those produced by using HDPE are stronger than those produced with PET.

Keywords:  Charcoal; recyclable binds; briquette; solid fuel


1. Introduction

Research centres and enterprises around the world are seeking alternative energy sources that can completely or partially replace fossil fuels. A consequence, biomass fuels (renewable source) have become particularly prominent. Recently, as an alternative to mineral coal, biomass-derived charcoal has been extensively studied1-3.

Biomass from elephant grass (Penisetum purpureum Schumach) presents C4 metabolism (high productivity of organic matter per hectare) which is found in abundance throughout the Brazilian territory at low management cost4-6. Its heating value is about 4200 kcal/kg and it has low mechanical strength for being a non-woody vegetable, thus not being favourable for direct burning in some cases7,8.

In addition to the energy consumption of non-renewable sources, there is a widespread increase in solid waste generation, such as plastic waste, which is most often not disposed of adequately (dumps), which increases environmental impacts even further. In August 2010, was enacted in Brazil a federal law No. 12.3059, which deals with the national solid waste policy that provides for the deactivation and recovery of dumps giving rise to controlled sanitary landfills with an adaptation period until 2021. The same law also provides for the implementation of recycling, composting and other treatments for solid waste in general. In this context, a noble destination of the part of this waste would facilitate the implementation of this law by the states and cities.

Donato et al.10 state that charcoal produced for metallurgical purpose should have mechanical strength equal to or greater than 70 kgf.cm-2. Other methods of pelletizing charcoal with thermoplastic binders or other amounts of these in the blend can improve the mechanical properties of briquette11.

An ecologically friendly solution to improve charcoal pellet properties would be pelletizing it with recyclable thermoplastic binding agents PET and HDPE11. PET and HDPE are easily separable from other solid wastes and have an average higher heating value close to biomass charcoal. Thus, elephant grass charcoal has been produced according to a preset rate heating12, blended and pelletized with recyclable thermoplastic binders (PET and HDPE). The obtained material has been characterised through physicochemical tests, such as high heating value (HHV), immediate chemical analysis, thermogravimetric analysis/differential scanning calorimety (TGA/DSC) and briquette compressive strength. An electron dispersive spectroscopy (EDS) elemental analysis of charcoal and its ashes has been performed in order to find its main constituents. In addition to the aforementioned techniques, a scanning electron microscopy (SEM) analysis has been carried out to visualize the charred material morphology.

2. Materials and Methods

Elephant grass charcoal has been prepared by using stems of its raw dry grass. Pyrolysis conditions selected for its production were: initial temperature (Ti) of 25 º C; final temperature (Tf) of 450 º C, heating rate of 10 º C. min.-1, and Tf has been kept for 120 min. using a carbon steel reactor (=95mm; L=130mm) in an inert atmosphere. After the charring process, its gravimetric yield was calculated.

In order to improve the physical and physicochemical properties of elephant grass charcoal aimed at being used as solid fuel, recyclable thermoplastics powder (PET and HDPE) have been added and mixed at mass percentages of 0 (pure), 5, 10 and 15% with powdered EGC, so that they can act as binding agents in pelletizing/briquetting. Both EGC, PET and HDE are smaller than Tyler Standard mesh 32. The obtained blends (elephant grass + binder) have been analysed by the following techniques: immediate analysis (NBR 8112); HHV (Parr instruments, model 3141); TGA/DSC (SDT 2960 Simultaneous DTA/TGA-TA Instruments); SEM/EDS (HITACHI-TM3000/BRUKER XFlash MIN SVE). Afterwards, blends were briquetted through hot compression (170ºC; 80 kgf/cm2) and then the briquettes underwent mechanical compressive strength analyses (SHIMADZU® AG-X Plus and software Trapezium X).

Sample preparation and analysis are presented in Figure 1:

Figure 1
Schematic diagram of sample preparation and analysis.

3. Results and Discussion

The average gravimetric yield of elephant grass charcoal was 29.42%. On average, the gravimetric yield of vegetal biomass processed at 450 ºC generates around 21 to 33%, depending on the age and type of plant. The obtained result is in agreement with results achieved by other researchers13-15.

The immediate analysis results of dry biomass samples are presented in Table 1, whose average moisture content of both samples was around 5.8% has been performed.

Table 1
Ash, volatile matter (VM), total fixed carbon (TFC) of pure charcoal and blends.

With respect to ashes, there were no significant alterations by adding the thermoplastic agents, although volatile material and fixed carbon contents have undergone significant variations concerning pure elephant grass charcoal.

According to Table 1, with the addition of PET, the pure elephant grass charcoal percentage of volatile material and fixed carbon contents ranged between (+) 22.5% and (-) 6.4%, respectively, whilst these values ranged between (+) 20.2% and (-) 6.7% with the addition of HDPE. These variations are due to the thermal decomposition of materials present in the thermoplastic polymers, since the majority of monomers present in their composition are C, H and O, thus presenting low content of nonvolatile contaminants.

Thermogravimetric analyses were performed in inert and oxidising atmospheres for pure charcoal and blends containing 15% of recyclable thermoplastics to verify possible events occurring in the thermal decomposition of samples. Figures 2 and 3 show the obtained results.

Figure 2
TG and DTG curves of samples in an inert atmosphere.
Figure 3
TG and DTG curves of samples in an oxidant atmosphere.

According to Figure 2a, the first event is observed between 30 and 115 º C which is due to sample moisture loss. For pure charcoal at temperatures ranging from 115 to 800º C, there is a linear mass loss of 15.42% on account of temperature increase by releasing volatile compounds and thermal decomposition of the non-charred material. On the other hand, both charcoal/polymer blends presented a marked event starting at approximately 400 º C and ending at 490 º C due to the thermal decomposition of polymers under study16-18.

In an oxidant atmosphere, two main events are observed. One is due to moisture loss at up to approximately 115 º C and an exothermic one on account of the thermal degradation of EGC and EGC with PET and HDPE19. As for the charcoal blended with thermoplastics, the greatest temperature variation is shifted in over 50 º C due to the fact that the combustion of binders occurs at higher temperatures18,20. According to Guo et al.20, PET undergoes thermo-oxidative degradation in two consecutive steps, first is relating to the degradation of the backbone and formation of a char and second is relating to the thermo-oxidative degradation of the char, at a temperature higher than that charcoal20.

The immediate analysis and TGA results reveal coherence in both the determination of volatile material and ash content. By disregarding the initial moisture found by the TGA in an oxidant atmosphere, the ash content obtained through this method is approximately 14%, i.e. close to the one found through the immediate analysis. The volatile material content, by disregarding the initial moisture content found by the TGA in an inert atmosphere, is 28.77% for PET and 25.00% for HDPE.

Table 2 shows the variations in the high heating value of blends concerning the pure elephant grass charcoal. The results indicate that the type of thermoplastic used for briquetting/pelletizing samples exerts influence on their calorific value. On average, the high heating value of PET is approximately 5222 kcal/kg21-23 and 5924 kcal/kg for the pure elephant grass charcoal, thus the addition of PET tends to reduce the blend’s calorific value, whilst the HDPE exerts inverse influence since its calorific value is higher than pure EGC, i.e. approximately 9543 kcal/kg23,24.

Table 2
Calorific value of pure elephant grass charcoal and charcoal blends with thermoplastics.

According to micrographs in Figures 44b, the chemical elements present in the charcoal structure and in its ashes have been identified and quantified. Light atoms with atomic weight below that of C could not be detected by the used technique. As observed by the EDS, charcoal is mostly composed of carbon (78%). This result differs from that obtained by the analysis of fixed carbon content (65%), given that EDS quantifies the carbon present in volatile matter (composed mainly of carbon, followed by hydrogen, oxygen and nitrogen). The other elements of charcoal, such as K, P, Al, Si, Mg and Al are probably as its oxides, come from salts which are essential for plant growth. In ashes, oxides of the elements cited above are found without C. An advantage of charcoal is its low quantity and/or absence of sulphur in its composition which, along with the fact that it is renewable, it becomes a fuel which is less harmful to the environment.

Figure 4
SEM / EDS for elephant grass charcoal and its ash.

Figure 5 presents a SEM of the structure of elephant grass charcoal. The structures observed in the micrographs shown in Figure 5 are the same for all analysed charcoal samples. It is also possible to observe the formation, according to some researches25-27, of channels related to the cell structure of the plant under analysis. These structures are formed from cellulose after the loss of hydroxyl radicals by thermal dehydration of the plant. For comparison, the diameter length of the hollow carbon tube of elephant grass charcoal (non-woody cellulosic plant) (15.51μm) is at least around two times larger than the diameter length of the hollow carbone tube of woody vegetables as Hymenaea aurea (8.86μm) and Eucalyptus alba (7.42μm) and five or more times larger than Mimosa Scabrella (3.9μm) and Tabebuia capitata (1.0μm)25. This characteristic results in less carbon network per volume of charcoal in non-woody vegetables like as EGC, resulting in lower mechanical resistance.

Figure 5
SEM images of elephant grass charcoal.

Since non-woody vegetables form charcoal with low mechanical resistance, the obtained EGC was milled and mixed with binders agents to form briquettes. Thereby, tests have been performed to determine the compressive strength limit of briquettes, whose results are presented in Table 3. According to the results shown in Table 3, an improvement in mechanical strength is achieved by the addition of binders to charcoal. Charcoal fines are not able to form briquettes without binders.

Table 3
Values of compressive strength limits for charcoal samples and briquettes formed from blends with binding agents.

The briquette produced with 15% HDPE presented optimal results due to obtaining tensile strength or compressive strength limit of 59.42 kgf.cm-2, i.e. 11 times higher than that of briquette produced with 5% PET. It was also observed that the higher the percentage of binder being used in the blend is, the greater the mechanical strength becomes.

As a comparison, Donato et al.10 obtained pellets of charcoal fines with different binders, in their work the compressive strength was not higher than 0.89 kgf.cm-2 while the high heating value was 6944.5 kcal/kg. Robinson et al.28 found a gross calorific value to wood pellet and wood-PET pellet as 4397.15 kcal/kg and 4767.36 kcal/kg, respectively.

4. Conclusion

The immediate analysis data show a fixed carbon content of 65% for charcoal and that the binder addition reduced it, in addition to an average ash content of 13%. Ashes obtained from elephant grass charcoal and its blends with the binding materials present a typical composition of this raw material. No traces of sulphur were found, which makes it a solid fuel with reduced environmental impact. According to heating value data (5559 to 6051 kcal/kg), it is possible to affirm that the material produced can be used as fuel and that the PET binder reduces the heating value of pellets. On the other hand, HDPE increases their heating value. The mechanical strength of obtained pellets increased by the addition of thermoplastic binders, and HDPE is the one that achieved the greatest compressive strength (59.42 kgf.cm-2). Based on the data obtained in this work, it is possible to try to implement a continuous briquetting process using a screw extruder and test different pressures and temperatures for briquetting. New recycled binding agents such as polystyrene, polypropylene and others can also be tested.

5. Acknowledgements

The authors are thankful to FAPEMIG for the master's degree scholarships and to Prof. José Antônio da Silva (UFSJ) for the calorific value analysis.

6. References

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Publication Dates

  • Publication in this collection
    17 Aug 2020
  • Date of issue
    2020

History

  • Received
    22 May 2020
  • Reviewed
    17 July 2020
  • Accepted
    19 July 2020
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