Mechanical and energy properties of pellets formed from walnut shells blended with spruce sawdust

Cajova Kantova, N., Caja, A., Belany, P., Kolkova, Z., Hrabovsky, P., Hecko, D., and Micko, P. (2022). "Mechanical and energy properties of pellets formed from walnut shells blended with spruce sawdust," BioResources 17(1), 1881-1891.

Abstract

Various waste materials have energy potential. It is important to make use of this potential and prepare the product for further use by treating the waste. Treatments such as compressing waste into pellets leads to increasing the energy density of this fuel, which benefits transport and storage costs. However, low bulk density, high ash content, low-ash melting temperatures, and low calorific values of non-woody pellets can cause problems during their combustion. This article deals with the energy usage of walnut shells, which were blended with spruce sawdust in various amounts and compressed into pellets. The mechanical and energy properties of these were measured and compared with recommended or standardized values. The formed pellets met the quality limit for bulk density, ash content, moisture content, the content of nitrogen and sulfur, and net calorific value according to ISO 17225. However, low ash melting temperatures were noticed for pellets from pure walnut shells, and also lower mechanical durability for produced pellets with walnut shells contents higher than 10% were detected.

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Mechanical and Energy Properties of Pellets Formed from Walnut Shells Blended with Spruce Sawdust

Nikola Čajová Kantová,^a,* Alexander Čaja,^b Pavol Belány,^a Zuzana Kolková,^aPeter Hrabovský,^a Dávid Hečko,^a and Pavol Mičko ^a

DOI: 10.15376/biores.17.1.1881-1891

Keywords: Waste utilization; Agricultural residual; Biomass; Biofuels; Pellet analysis

Contact information: a: Research centre, University of Zilina, Univerzitna 1, Zilina 010 26 Slovakia; b: Department of Power Engineering, Faculty of Mechanical Engineering, University of Zilina, Univerzitna 1, Zilina 010 26 Slovakia; *Corresponding author: nikola.cajovakantova@uniza.sk

INTRODUCTION

Residual biomass is an important resource to produce energy and is vital in reducing emissions that are typical for fossil fuels. It can be considered carbon-neutral, which is in a line with the interest of the European Union. In general, biomass and also residual biomass has a high moisture content, low mass, and low energy density, which lead to decreasing in heat output (Picchio et al. 2020). This makes it difficult to handle, transport, and store the biomass in its unprocessed form. The solution to these problems can be pelletization because this process leads to the increasing of energy density, besides reducing transport and storage costs. Pellets formed from residual biomass are more homogeneous than unprocessed materials (García et al. 2019).

Wood represents the main component in most formed pellets. It is used as an input material mainly in the form of wood sawdust (Jandačka et al. 2013). In addition to wood, various agricultural residues are also used as the main input materials. However, the quality of such pellets generally is lower than that of wood pellets. The main problems are their low bulk density, high ash content, low ash melting temperatures, and low calorific values (Picchio et al. 2020). Increasing bulk density increases the energy density and decreases transport and storage costs. High ash content causes fouling of furnace equipment and it is important to often empty of ash box. High ash content and low ash melting temperatures also lead to the creation of deposit formation, slagging, and sintering (Matúš et al. 2018). When combusting this type of fuel, the kind of burner used as well as the combustion conditions are important to take into account (Werle and Dudziak 2014). The work of Pafčuga et al. (2021) states that a rotary burner allows the combustion of different types of biomass. The rotary burner was also used during the combustion of pellets formed from lawn clippings, corn husks, linden leaves, and pine needles in the work of Trnka et al. (2021). According to Matúš et al. (2018), it is also important to reduce the temperature in the burner place.

Without further use of agricultural residues, the materials often are left to rot in landfills. In the work of García et al. (2019), pellets for industrial usage were produced from pine sawdust and from 11 different biomass residues. It was found that the nitrogen and ash content can be the most important parameters in selecting the ratio of biomass residues and pine sawdust to meet the industrial quality. To ensure industrial quality, one could use only a maximum of 30% for almond shells, coffee dregs, olive stones, and pinecone leafs, a maximum of 15% for hazelnut shells, miscanthus, pine kernel shells, and switchgrass, and a maximum of 10% for coffee husks and grape pomace. The results confirmed that it is possible to create pellets that meet industrial quality by using alternative biomass residues. Rezaei et al. (2020) produced even pellets from paper, plastic, household organic, and wood. Individual components were ground, wetted to 20% moisture content, and subsequently pelletized. The higher content of plastics from 20% up to 40% led to a reduction in energy consumption for pellet production and increased their calorific values. The higher content of paper from 30% up to 50% increased the durability of the pellets, but more energy was expended to produce them. Grabowski and Smoliński (2021) tested pellets produced from wood mixed with various types of waste, such as plastic, rubber, paper, diapers, construction, and so on. However, it is necessary to control the usage of waste or other lower-quality fuels in the combustion process.

Nuts crops cover close to 1,200,000 ha in Europe, and nut waste is up to 40% of the harvested matter (Noszczyk et al. 2021). The energy and kinetic parameters of various nut shells (walnut, hazelnut, peanut, and pistachio) were investigated in the cited work. The results showed that raw nut shells had relatively high calorific values (17.8 to 19.7 MJ/kg) and moisture content in the range of 4.32% to 9.56%. The elemental characteristics of individual nut shells were found to be similar, but the highest nitrogen content was found in peanut shells. In the work of Acampora et al. (2021), pruning residues from hazelnut and olive groves were used for pellet production. The results showed good quality pellets were produced in terms of profit and energy potential. The ash content, bulk density, and nitrogen content in the case of olive pellets did not meet the legislative requirements. To meet the legislative requirements, the authors proposed to mix the used residues with wood residuals. One of the goals of the work of Perea-Moreno et al. (2018) was to investigate peanut residues in terms of energy potential and thus evaluate the energy parameters of peanut shells as biofuels. The authors found that peanut shells have higher calorific values compared to olive stones or almond shells. However, the ash content of peanut shells is higher than olive stones or almond shells. Almond shells have been the subject of research in terms of anatomical and chemical properties in the work of Li et al. (2018). The content of lignin was also determined in various types of nutshells. Walnut shells had the highest content of lignin (43.70% ± 0.57%).

It is important to use the energy potential of various waste materials in line with the decreasing of emissions compared to fossil fuels. This article deals with the usability and testing of walnut shells in pellets in various amounts given by their weight proportions. They were blended with spruce sawdust for the production of pellets. Pellets were created using a small pellet press. Then they were tested for their mechanical and energy parameters, such as bulk density, particle density, mechanical durability, elemental analysis, proximate analysis, calorific values, and ash melting temperatures. Their properties were compared with recommended or standardized values for their further application.

EXPERIMENTAL

In this work spruce sawdust and walnut shells were used as input materials as stated in Fig. 1. Walnut shells were shredded using an industrial blender. The original moisture content of spruce sawdust was in the range of 45% to 55% (wet basis). It was necessary to dry them in the laboratory to bring it up to 12% to 16% (dry basis). The original moisture of walnut shells was 8% to 9% (wet basis), and this material was not dried further.

Fig. 1. Input materials: a) Spruce sawdust; and b) Walnut shells

The particle size distribution of the input materials was obtained using vibrating sieve equipment Retsch AS200 (Retsch GmbH, Haan, Germany). Figure 2 shows the difference and weight proportion of spruce sawdust and walnut shells. Both samples had a started weight about of 100 g.

Fig. 2. Particle size distribution

The difference in particle size was probably due to the crushing process. The used crusher could not crush harder materials, such are walnut shells, into such small particles. The sieve analysis showed a difference in particle size in the materials used, where the spruce sawdust had a higher amount of particles up to 1 mm and the sample of walnut shells showed the highest concentration of particles above 1 mm.

Input materials were compressed together into pellets using the small pellet press LPBB200V2. In this work, pellets were produced from walnut shells containing spruce sawdust in the different proportions (see the Table 1). The individual pellet samples are stated in Fig. 3.

Table 1. Compositions of Pellet Samples

Fig. 3. Pellet samples: a) 0/100; b) 10/90; c) 20/80; d) 30/70; e) 40/60; f) 50/50; g) 60/40; h) 70/30; i) 80/20; j) 90/10; k) 100/0

The pellet press operated with an output of 7.5 kW and at a lower pressure than that achieved with larger industrial pelletizers. The created pellets were produced under the same conditions and had a diameter of about 6 mm. All pellet samples were stored in a laboratory at the temperature of 20 °C and relative humidity from 40% to 50%. After one week of storage, the properties of created pellets were tested.

The formed pellets were tested for their mechanical and energy parameters, such as bulk density, particle density, mechanical durability, elemental analysis, proximate analysis, calorific values, and ash melting temperatures.

The bulk density was calculated from the net weight per defined volume according to ISO 17828 (2015). The particle density was determined as the ratio between weight and volume of pellets. In this case, pellet weight was measured by digital weight, and volume was calculated as a cylinder volume with its length and diameter according to ISO 17829 (2015). To achieve parallel faces of the pellets, the individual areas were sanded.

The mechanical durability was measured using a Ligno-Tester Holmen device (Tekpro Ltd., North Walsham, UK). The pellet samples of 100 g were put in a Ligno-Tester and rotated there for 60 s, while they were subjected to controlled impacts. Differences between pellet weight before and after the test allow the calculation of mechanical durability.

The elemental analysis was realized on an elemental analyzer CHN628 (Leco Corporation, St. Joseph, MI, USA) with a separate module for the determination of sulfur content. Individual samples were weighed with an approximate value of 0.1 g for the detection of C, H, and N and of 0.25 g for sulfur detection. Pre-weighed samples were combusted in the absence of atmospheric gases. After this combustion in the combustion chamber, the contents of C, H, and N gases can be detected. The presence of sulfur content was detected in the separate module at a higher temperature of about 1350 °C.

The proximate analysis was realized using a thermogravimetric analyzer TGA 701 (Leco Corporation, St. Joseph, MI, USA). This analyzer measures the weight loss of samples in a defined atmosphere, while their temperatures are gradually increasing. Using this device, it can be possible to determine the content of moisture, volatile matter, fixed carbon, and ash. Individual samples were weighted with an approximate value of 1.2 g and heated at 107 °C for the determination of moisture content in the air atmosphere. Then the temperature was increased at 900 °C for the determination of the volatile matter in the nitrogen atmosphere. Finally, the temperature was decreased at 550 °C in air atmosphere, where ash content was detected.

The measurement of higher calorific values was realized on a calorimeter Leco AC 500 (Leco Corporation, St. Joseph, MI, USA). Individual samples were weighed with an approximate value of 1 g. Lower calorific values were calculated using measured higher calorific values using Eq. 1.

(1)

(2)

Equation 1 contains r_H2O, which denotes water heat of vaporization (kJ/kg); W_p represents the water content (wt.%); hydrogen to water conversion coefficient with the value of 8.94; and x_H is obtained from Eq. 2. In Eq. 2, H_h is the hydrogen content (wt.%), and B_p is volatile content (wt.%) of tested samples (Nosek et al. 2021).

The determination of ash melting temperatures was realized using a temperature analyzer Leco AF 700 (Leco Corporation, St. Joseph, MI, USA). This analyzer measures four standardized ash-melting temperatures: (1) The shrinkage temperature (ST); (2) the deformation temperature (DT); (3) the hemisphere temperature (HT); and (4) the flow temperature (FT). Investigated temperatures were determined according to ISO 540 (2008).

All measurements were repeated three to five times, with the resulting values being their mean values with the calculated sample standard deviation. Determination of sample standard deviation was performed for all measurements according to Eq. 3.

(3)

In Eq. 3, n is the sample size, is the individual sample values, and is the sample mean.

RESULTS AND DISCUSSION

Results from the measurement of bulk density are shown in Fig. 4. All tested pellets had bulk density higher than 600 kg/m³, but lower than 700 kg/m³. Wood pellets used for commercial and residential applications including non-woody pellets (made from herbaceous, fruit, and aquatic biomass, and also mixtures with wood) should have a bulk density higher than 600 kg/m³according to ISO 17225 (2014). This limit was achieved for all tested pellets prepared from spruce sawdust and walnut shells.

Fig. 4. Bulk density of tested pellets: (0/100) The weight proportion of walnut shells is 0% and the weight proportion of spruce sawdust is 100%; (10/90) The weight proportion of walnut shells is 10% and the weight proportion of spruce sawdust is 90%; and so on

Fig. 5. Particle density of tested pellets

Figure 5 shows results from the measurement of particle densities of formed pellets. All tested pellets had particle density in the range from 1081 kg/m³ to 1268 kg/m³. Wood pellets have a recommended value of particle density in the range from 1000 kg/m³ to 1400 kg/m³ according to Stelte et al. (2011). These recommended values are attained for all tested pellets.

Results of the measurement of mechanical durability (DU) are indicated in Fig. 6. Wood and non-woody pellets should have mechanical durability higher than 97.5% to meet the limit of quality A and higher than 96.5% (wood) or 96.0% (non-woody) to meet the limit of quality B according to ISO 17225 (2014). Pure pellets from spruce sawdust met the limit value for quality A. Pellets with 10% of walnut shells met the limit value for quality B. Other formed pellets did not pass the test of mechanical durability. The mechanical durability can be also increased using additives, such as concentrate of organic compounds (Jandačka et al. 2013).

Fig. 6. Mechanical durability of tested pellets

Table 2. Elemental Analysis of Tested Pellets

Table 2 shows the results of elemental analysis such as the contents of C, H, and N. The content of sulfur was not detected. Wood pellets should have a N-content lower than 0.3% and a S-content lower than 0.04% to meet the limit of quality A1 according to ISO 17225 (2014). Non-woody pellets should have a N-content lower than 1.5% and a S-content lower than 0.2% to meet the limit of quality A according to ISO 17225 (2014).

All tested pellets met the limit values for contents of nitrogen and sulfur for quality A. It can be seen that the contents of carbon and hydrogen increased slightly with increasing the content of walnut shells.

Table 3 shows the results of proximate analysis, such as the contents of moisture, volatile matter, fixed carbon, and ash. Wood pellets should have a moisture content lower than 10% (for non-woody pellets lower than 12%) to meet the limit of quality A according to ISO 17225 (2014). All tested pellets had a moisture content lower than 10%. As ash content for wood pellets should be lower than 0.7% to meet the limit of quality A1 according to ISO 17225 (2014), pure pellets met this limit. However, all non-woody pellets also met the limit in their category. The ash content for non-woody pellets should be lower than 6% to meet the limit of quality A and lower than 10% to meet the limit of quality B.

Table 3. Proximate Analysis of Tested Pellets

Fig. 7. Calorific values of tested pellets

The calorific values are quantified in Fig. 7. Wood pellets should have a net calorific value (also known as lower calorific value) higher than 16.5 MJ/kg, and non-woody pellets should have a net calorific value higher than 14.5 MJ/kg to meet the limit of quality A and B. This limit was met for all pellets formed from pure spruce sawdust and also from non-woody materials as pure walnut shells or their mixture with spruce sawdust. With the increasing amount of walnut shells, the calorific values also were increased.

Figure 8 presents results from the measurement of ash melting temperatures. The maximum working temperature used in the analyzer was 1500 °C. The spruce wood has the following ash melting temperatures: (1) DT in the range from 1110 °C to 1340 °C; (2) ST in the range from 1410 °C to 1640 °C; (3) HT in the range from 1630 °C to 1700 °C; and (4) FT higher than 1700 °C according to Van Loo and Koppejan (2008). In general, non-woody biomass has lower values of ash melting temperatures than wood biomass, which is also confirmed by the measured results. Pure pellets from walnut shells had the lowest ash melting temperatures. Low ash melting temperatures of fuels can cause sintering or slagging during their combustion.

Fig. 8. Ash melting temperatures of tested pellets: (DT) Deformation temperature; (ST) Shrinkage temperature; (HT) Hemisphere temperature; (FT) Flow temperature

CONCLUSIONS

All pellets formed from spruce sawdust and walnut shells met the quality limit for bulk density, ash content, moisture content, the contents of nitrogen and sulfur elements, and net calorific value according to ISO 17225 (2014). However, most of the measured values of mechanical durability were lower than stated in this standard.
Measured values of ash melting temperatures were decreasing with the increasing content of walnut shells, which can cause sintering or slagging during combustion. It is recommended to mix non-woody material with wood material, which increases ash melting temperatures compared with pure non-woody material.
Based on the results, it can be concluded that walnut shells are useable agricultural residuals in the pelletization process as input material by blending with spruce sawdust for heating purposes.

ACKNOWLEDGMENTS

This publication has been produced with the support of the Integrated Infrastructure Operational Program for the project: Creation of a Digital Biobank to support the systemic public research infrastructure, ITMS: 313011AFG4, co-financed by the European Regional Development Fund and Grant System of University of Zilina No. 1/2021 (13832).

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Article submitted: October 25, 2021; Peer review completed: January 1, 2022; Revised version received and accepted: January 18, 2022; Published: January 28, 2022.

DOI: 10.15376/biores.17.1.1881-1891