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Article

Catalytic Microwave-Assisted Pyrolysis of the Main Residue of the Brewing Industry

Chemical Engineering School, Federal University of Uberlândia, Uberlândia 38408-100, Brazil
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Author to whom correspondence should be addressed.
Catalysts 2023, 13(8), 1170; https://doi.org/10.3390/catal13081170
Submission received: 6 June 2023 / Revised: 21 July 2023 / Accepted: 26 July 2023 / Published: 30 July 2023
(This article belongs to the Special Issue Chemical Catalysis for Waste Plastics Recycling and Upcycling)

Abstract

:
Most agro-industrial wastes are lignocellulosic biomass. Several technologies have been developed to convert these residues to value-added products. Among these processes, pyrolysis refers to the thermal degradation of organic materials. Microwave-assisted pyrolysis (MAP) is more advantageous than conventional pyrolysis because it offers time savings, increases heating efficiency, and promotes a more precise process control. In this work, the microwave-assisted pyrolysis (MAP) of brewer’s spent grain (BSG), the main waste of the brewing industry, was studied, focusing on its liquid product. The effects of temperature, moisture content, and catalyst (calcium oxide) percentage on the product distribution and hydrocarbon content in the liquid product obtained were investigated. Although a high liquid yield of 71.8% was achieved with a BSG moisture content of 14%, the quality of the product (hydrocarbon yield) in this condition was not so attractive (21.60%). An optimization study was carried out to simultaneously maximize bio-oil yield and quality. The optimum conditions obtained were a temperature of 570 °C and a catalyst/biomass ratio of 12.17%. The results of the liquid product composition at the optimum point are promising given the presence of aromatic hydrocarbons, organic compounds of great interest to the industry.

1. Introduction

The valorization of underutilized agro-industrial wastes represents a significant opportunity in view of the growing demands for energy, the impacts of fossil fuel on the global environment, and people’s concern with the improper disposal of solid wastes because of their serious impact on global warming and land use. These concerns have encouraged the development of alternative technologies to use these wastes for the generation of clean and renewable energy [1]. Pyrolysis is a thermochemical technique used to decompose biomasses into different products, such as bio-oil or other high-value chemicals, combustible gases, and biochar [2,3,4].
Brewer’s spent grain (BSG) is the main by-product of the brewing industry, representing 85% of the total by-products generated in the brewing process [5,6]. This lignocellulosic material can be used in a thermochemical conversion process such as pyrolysis as a source of high-value products or as a petroleum fuel substitute in the long term [7,8,9].
The valorization of BSG was recently studied using conventional sources of heating in a fixed bed reactor to perform the slow pyrolysis, and a high liquid yield was achieved (60.7%) at 650 °C [10]. In addition, some work was also performed to study the fast pyrolysis and the fluid dynamics behavior of mixtures of sand and BSG in a spouted bed. The authors found a bio-oil rich in phenolic and nitrogenated compounds [7]. Some kinetic studies on the pyrolysis of BSG were also performed [9,11,12]. However, in these previous works of the BSG pyrolysis, the heating was performed using an electrical source, which is inefficient and energy-intensive.
Alternative heating systems for the pyrolysis process have been investigated in the last decades [13,14,15,16]. The microwave-assisted pyrolysis (MAP) process offers some advantages over traditional pyrolysis, such as precise, controlled, and selective heating [17,18,19,20,21]. Despite these advantages, there are still several challenges to be overcome—for instance, the low bio-oil yield compared to that obtained in conventional configurations for some types of biomass [22]. Therefore, in order to transfer this pyrolysis technology to the industrial sector, further studies are needed to overcome this and other issues, e.g., the quality of the obtained products [23,24,25].
The yield and quality of the bio-oil obtained via MAP can be significantly affected by the characteristics of the raw material [26,27]. For example, although the moisture content of biomass can improve the overall efficiency of microwave radiation energy absorption [28], a very high moisture content can impair the bio-oil quality [29,30,31]. Most of the studies employing MAP used a biomass moisture content lower than 16% (wet base) [32,33,34,35]. Nonetheless, it is still a challenge to find the best moisture content in order to improve the yield and quality of pyrolysis products.
There is an increasing amount of research studies focused on the use of microwaves in the pyrolysis of biomass feedstocks, such as corn stover [29,36], pine sawdust [32,37,38,39], bamboo sawdust [39,40], oil palm male flowers [41], palm kernel shells [42], oil palm empty fruit bunches [43], rice husks [44,45,46], macadamia shells [47], wood [48,49], sugar cane bagasse [50,51], walnut shells [52], orange peels [53], banana peels [54], and seeds [55,56], among others. According to these publications, the use of microwave heating in the pyrolysis of biomass can enhance the production of biofuels and chemicals products. However, the results are strongly dependent on process parameters.
Some of the latest research in microwave-assisted pyrolysis has demonstrated the importance of this method to achieve the production of different products of interest, especially liquid products. One of these publications addresses the production of aviation oil using plastic waste as feedstock for the MAP. The authors point out that the liquid product obtained showed many hydrocarbons of a long chain. For polypropylene, for example, C8–C16 hydrocarbons were 91.02% of the area. This work highlights microwave-assisted pyrolysis as a method to successfully achieve the production of fuels [57]. The interest in contributing to the development of alternative sources of energy, such as biofuels, has also led to some studies using MAP of microalgae (Chlorella vulgaris) and low-rank coal with 1 wt.% HZSM-5 catalyst. The authors found a bio-oil yield of 33.8 wt.% in the best conditions, with a composition composed of several groups, including hydrocarbons [58]. Another publication compared pyrolysis using microwave heating and electric heating of spent bleaching clay, and the authors addressed that the microwave heating saved up to 53% of the energy consumption in the proposed comparison, resulting in high production of aromatics in the bio-oil [59]. Several studies state the strong sensitivity of the yield and quality of the microwave-assisted pyrolysis products to the operational parameters [60,61,62,63,64,65].
The effects of catalysts on thermochemical conversion processes of biomass have been the focus of many researchers [35,66,67,68,69]. Catalyst selectivity is important for optimizing the distribution of products and improve their quality. In this study, we choose calcium oxide (CaO) as the catalyst because it is a cheap catalyst when compared to zeolites and other catalysts. Additionally, a CaO catalyst has the ability to improve the composition of the liquid product, especially related to its action in the decarbonylation of ketones, which results in the formation of CO and hydrocarbons. Chen et al. [70] worked on the pyrolysis of cellulose, hemicellulose, and lignin—the main components of lignocellulose biomasses—in the presence of CaO, and they found that at temperatures ranging from 400 °C to 600 °C, the use of CaO contributed to the conversion of acids. Regarding cellulose, the CaO reduced the yield of sugars that suffer from catalytic cracking at higher temperatures. Concerning the use of CaO in the pyrolysis of lignin, the authors found that at these temperatures, phenol content decreases [70]. Thus, based on this and other results of the literature [71,72,73,74,75,76], it is expected that the addition of calcium oxide in microwave-assisted pyrolysis of BSG can produce a liquid product with low acids and phenols contents and high hydrocarbon yields.
Catalytic pyrolysis can be classified as in situ or ex situ. In the first case, the catalyst is mixed with the biomass, and in ex situ configurations, the biomass is pyrolyzed separated and the catalyst is kept in a catalyst bed [77]. The reusability of the spent catalyst is an important factor. In this work, the use of spent CaO was not performed because we used in situ configuration. However, many authors have reported these studies in pyrolysis, especially in ex situ configurations. Yi et al. [78] studied the ex situ catalytic pyrolysis of biomass (Jatropha seeds cake) in a fixed-bed reactor and compared the use of different CaO (organic and conventional). In their study, they mentioned that ex situ configuration contributes to the separation of char and CaO. Furthermore, they showed that the regeneration of the spent CaO was performed via calcination in a muffle furnace at 900 °C for 0.5 h, conditions capable of completely removing the coke deposition for the conventional CaO regenerated 10 times over. Gupta et al. [79] performed fast pyrolysis of oakwood using partially hydrated CaO, and according to them, the catalyst showed good structural stability after catalytic tests. Kumagai et al. [80] studied the pyrolysis of polyethylene terephthalate (PET) using calcium oxide. In terms of GC area percentages, they found that over 10 repetitions, the product distribution in the CaO catalysts analyzed did not show significant changes. Castello et al. [81] also reported that in catalytic pyrolysis of biomass, the in situ configuration deals with the difficulty in distinguishing the catalyst and biochar.
Despite many efforts made in many studies of the pyrolysis of different materials using different catalysts, additional studies of the catalytic microwave-assisted pyrolysis are necessary to overcome some limitations of this technique, mainly related to the product quality, which is strongly affected by moisture content, type of catalyst, and other operating parameters.
In this work, the microwave-assisted pyrolysis of BSG was investigated for the first time with the aim of improving the performance of this methodology for the valorization of this underutilized agro-industrial waste. A detailed statistical analysis was performed using regression techniques to quantify the effects of temperature (T), moisture content (MC), and calcium oxide ratio (% Cat) on the yield of the three pyrolysis products, i.e., gas, liquid, and char. An optimization study was also carried out to find the ideal conditions for a high liquid product (bio-oil) yield with a high hydrocarbon yield.

2. Results and Discussion

2.1. MAP Products Yields

The yields of the three products obtained in the first central composite design (CCD) for the MAP process of BSG are presented in Table 1.
Kinetic studies on the pyrolysis of BSG were performed previously by our research group and is reported in a related paper [9]. The highest liquid yield was 71.9 wt.%, as observed in run 8 carried out at a temperature of 500 °C and a BSG moisture content of 14%. This result is higher than most of the values reported in the literature for microwave-assisted pyrolysis processes of various biomasses. Borges et al. [34] used samples of wood sawdust with a moisture content (MC) of 5.15% and semi-continually dropped them into the reactor, obtaining organic condensates with 65 wt.%. Huang et al. [82] studied the pyrolysis process of rice straw with an MC of 5.46% and obtained liquid production with a maximum of about 50 wt.%. Shang et al. [83] investigated the microwave-assisted pyrolysis of sawdust with an MC of 15.87% and activated carbon as additive, achieving a liquid product yield of approximately 28 wt.%. Mamaeva et al. [84] studied the catalytic microwave pyrolysis of peanut shells with an MC of 8.03 wt.% using activated carbon in a ratio of 8:1 at 500 °C and obtained a liquid yield of 16.62 wt.%.
As observed, high moisture contents of biomass, as is the case of run 8 (14%), favor the overall efficiency of microwave radiation energy absorption; thus, the bio-oil yield is significantly affected by the aqueous fractions [85]. According to some authors, the content of water in the liquid product of pyrolysis is one of the main problems to promote its use as fuel. In addition, the water content in pyrolytic liquid also impacts the storage step due to the corrosiveness and microbial activity [30,86]. Further studies are still needed to determine the entire effects of high moisture content on pyrolytic liquid product quality. Based on comparative studies with different catalysts for the fast pyrolysis of cotton stalks, Chen et al. [87] observed that CaO had the best behavior contributing to the low moisture content in the liquid product.
The liquid product obtained from the MAP of BSC in each experiment of the first CCD was analyzed by GC/MS. The detected compounds were classified into three different groups (hydrocarbons, oxygenated compounds, and nitrogenous compounds), and the respective results are listed in Table 2. The highest hydrocarbon content was obtained in run 7, which was performed at 500 °C and with the lowest moisture content (3.95%). Hydrocarbons are valuable components in bio-oil from the point of view of fuel application. Aromatic hydrocarbons serve as important industrial chemicals and fuel additives to increase the octane number [21].
The experimental results of the first central composite design (Table 1 and Table 2) were used to quantify the effects of the studied independent variables (T and MC) on the liquid and hydrocarbon yields using regression techniques. Table 3 shows the results of the statistical analysis with the significant values of each independent variable (T and MC), including linear, quadratic, and interaction coefficients. The analysis of the variance framework was used to determine the significance of the parameters. A factor or interaction was considered significant when the p-value satisfied the relationship p < 0.05 for a confidence level of 95%. Thus, factors or interactions with p > 0.05 were considered statistically non-significant.
Figure 1 shows the surface and contours for liquid and hydrocarbon fraction yields as functions of the independent variables (T and MC) obtained by the parameters in Table 3. As observed, the increase in temperature caused more volatile materials to be released, resulting in greater bio-oil production. Therefore, the highest liquid yield was obtained at temperatures around 500–550 °C (Figure 1a). The linear effect of MC on the bio-oil yield indicates that higher BSG moisture contents also lead to a high liquid yield. This suggests that high moisture contents in the wet biomass improve the efficiency of microwave radiation energy absorption, which in turn favors the pyrolysis process. However, the bio-oil obtained can be diluted by the aqueous fractions, which ends up affecting its quality, as seen in Figure 1b. The condition that simultaneously improved both responses (liquid and hydrocarbon yields) was a temperature around 500 °C and a low moisture content.

2.2. Catalyst Characterization

The results obtained from the X-ray diffraction (XRD) analysis of the catalyst (calcium oxide) used in the catalytic MAP experiments reveal characteristics of a homogeneous catalyst consisting mainly of pure CaO, calcium carbonate, and calcium hydroxide, as shown in Figure 2.
As it can be seen in Figure 2, the XRD pattern of the catalyst exhibits a strong peak in the 2θ range of 28.5–30.0 and five small weak peaks in the 2θ range of 36.0–48.6 due to the formation of calcium carbonate. In addition, there are peaks in the 2θ range of 33.4–54.3 which are typical of pure calcium oxide. There are also characteristic peaks of calcium hydroxide that can be associated with the fact that water was absorbed from the environment [88].
The results of the thermogravimetric (TG) and differential thermogravimetric (DTG) analyses of the fresh CaO catalyst used in this work as well as the spent CaO catalyst (after run 6) are shown in Figure 3.
According to Figure 3a, the TG/DTG curves of the fresh CaO catalyst show two events of mass losses. The first loss between 50 and 470 °C can be related to the water loss on the CaO surface kept by hydrogen bonds [89]. The water adsorption on this metal oxide happens due to the contact of CaO with moisture during exposure in the handling step [90,91]. The second mass loss occurs between approximately 650 and 762 °C and is related to the decomposition of calcium carbonate (CaCO₃), resulting in calcium oxide (CaO) and CO₂ formation [89]. According to Figure 3b, the TG/DTG curves of the spent CaO after run 6 (570 °C and 15 cat %) also show two weight losses. The results of the spent catalyst and the CaO prior to the experiment showed similar behavior, and as mentioned in previous works [77,78], they show good potential for reusability. Zhang et al. [92] also reported analyzes of CaO after the pyrolysis of poplar, cellulose, and lignin, and they showed that the slight difference observed in the spent catalysts was due to the coke deposits.

2.3. Catalytic Effects on the Distribution of MAP Products

The results of the products obtained from the catalytic MAP of brewer’s spent grain are summarized in Table 4. As can be seen, the formation of liquid product was significantly affected by the presence of the catalyst.
In general, the addition of the catalyst (CaO) to the microwave-assisted pyrolysis process (Table 4) resulted in a reduced bio-oil yield compared to the values obtained without the use of the catalyst at the same temperature (Table 1). The use of CaO promotes the cracking of bio-oil components, consequently increasing the gas yield. This difference is influenced by the pyrolysis temperature, since higher temperatures are more favorable to the cracking of volatiles in the presence of CaO [93,94,95]. However, despite the decrease in the liquid product yield, the quality of the bio-oil obtained in this study improved when the pyrolysis process was carried out in the presence of the catalyst according to the results of the GC/MS analysis (Table 5).
The GC/MS analysis of the liquid product yields showed that the content of hydrocarbons present in the bio-oil drastically increased, while the content of oxygenated compounds was reduced when the catalyst (calcium oxide) was used in the MAP. As reported, the CaO can promote bio-oil deoxygenation through decarboxylation and dehydration reactions, which ends up improving its quality [73,95]. The use of CaO can also have a deacidification effect, decreasing the content of oxygenated species, such as formic acid, acetic acid, and levo-glucose during the pyrolysis of biomasses [72,96].
The yield of ketones (oxygenated compounds) decreases in the presence of CaO due to the catalytic decarbonylation of linear ketones to form carbon monoxide at high temperatures [72]. CaO also reacts with phenols, promoting the cracking of the branched chain of phenols at high temperatures to form hydrocarbons and CO [70,97]. Figure 4 shows the composition of the bio-oil obtained from MAP of BSG carried out at a temperature of 550 °C using different CaO/biomass ratios (0%, 5%, 10%, 15% and 20%). As can be seen, the increase in the catalyst ratio (Cat %) reduced the oxygenated compounds and increased the hydrocarbons present in the liquid product.
The results of the liquid and hydrocarbon yields obtained in the experiments performed with the catalyst (Table 4 and Table 5) were statistically treated using regression techniques to quantify the effects of the independent variables (T and Cat) on these responses. Table 6 shows the results of parameters related to the linear, quadratic and interaction effects of these variables, together with the respective variance analysis. The parameters with a p-value higher than 0.05 were considered non-significant.
As observed, both variables (T and Cat) significantly influenced the bio-oil and hydrocarbon yields but did so in a non-linear way. This non-linear effect can be explained by two competing factors: the higher gas residence time due to the presence of the catalyst in the bed and the occurrence of secondary thermal cracking reactions [70,96].
Figure 5 shows the response surface and the respective contours for liquid and hydrocarbon fraction yields as functions of the studied independent variables. Considering both responses simultaneously, the best conditions for the studied variables were higher temperatures (T) and intermediate catalyst ratio (Cat) values. However, to find the most precise optimum condition, it was necessary to perform an optimization study.

2.4. Optimization Study and Analysis of Products

In this work, a multi-response optimization was performed to find the operating conditions that simultaneously maximized the bio-oil yield and its hydrocarbon content. The optimization study was carried out using the Desirability function [98]. In this technique, the composite function that combines the individual responses in the best way is named Global Desirability [99] and is commonly used in the RSM framework. The desirability values vary between 0 and 1, 0 being an undesirable response and 1 a desirable value [16].
Table 7 shows the optimization results with coded and real values of the independent variables for the optimum conditions as well as the respective values of liquid product (y₁) and hydrocarbon (y₄) yields calculated using the respective prediction equations. The optimum conditions obtained were a temperature at the highest level (570 °C) and a catalyst percentage of 12.17%. Table 7 also includes the results of a confirmatory experiment performed under these optimum conditions. The experimentally obtained hydrocarbon yield (y₄) was higher than that achieved in all runs of the central composite design (CCD) (Table 5) and in most of the results reported in the literature for biomass pyrolysis [29,33,84]. This result confirms the high quality of the bio-oil obtained from the MAP under these optimum conditions.
The liquid product obtained in the experiment carried out under the optimum conditions (a temperature of 570 °C and a catalyst percentage of 12.17%) was analyzed by GC/MS. Table 8 lists the main compounds found.
According to Table 8, the bio-oil produced has a diverse composition, in which the high content of hydrocarbon compounds (61.58%) stands out. Although substantial amounts of hydrocarbons are desirable for their use as fuel oil, this liquid product from the catalytic MAP can also be a source of value-added chemicals and therefore a supply of intermediary chemical species, such as phenolic compounds and aromatic hydrocarbons, among others. Phenolic compounds are also used in the food industry as flavorings, in the manufacture of adhesives and polymers, and as intermediates in pharmaceutical syntheses [9,29,100,101,102,103]. In addition, as reported by other authors, CaO was effective in removing acids with high oxygen content [95]. A low % area related to the acids was also found in all the experimental runs of the catalytic MAP of BSG (see Supplementary Material).
Some experiments of the CCD of the catalytic MAP were selected to analyze the physicochemical properties (water content and viscosity) of the liquid product generated. The results obtained are presented in Table 9.
It can be seen that the lowest water content in the liquid product was obtained in the experiment carried out with the highest catalyst loading (22%), evidencing the good performance of the CaO catalyst in reducing the water content of the bio-oil. Similar behavior for the water content in the liquid product was found in a study about the catalytic MAP of corn stover [29].

2.5. Solid Product Characterization

Scanning electron microscopy (SEM) analysis was used to analyze the morphological changes caused by the thermal degradation of brewer’s spent grain. Figure 6 shows SEM photomicrographs of the BSG at 50 and 200× magnification and of the solid product obtained from the microwave-assisted pyrolysis carried out under optimized conditions (temperature equal to 570 °C and 12.17% catalyst ratio). The surface of the solid product from the MAP optimization experiment is not homogeneous, with fibrous texture regions due to the influence of the thermal degradation of the biomass [10].

2.6. Catalyst Action

Calcium oxide is known to show significant deoxygenation activity when used in the pyrolysis of biomass [104]. Wang et al. [75] studied the pyrolysis of corncob using CaO as catalyst. They explained that the reduction in the number of acids generated as a product can also be related to the neutralization reaction, which originates calcium carboxylate and water. In addition, the authors also mention that some reactions involving CaO and phenols can be responsible for the formation of hydrocarbons at low temperatures [75]. Chen et al. [95] reported in their publication that, the calcium carboxylate is decomposed to CaCO₃ and ketones. According to Li et al. [72] the deoxygenation reaction of oxygenated compounds with calcium oxide catalyst can be represented by three pathways: neutralization (represented by Equations (1) and (2), thermal cracking (represented by Equation (3)), and catalytic cracking (Equation (4)), as shown below [75,105,106]:
CaO + 2 R   -   COOH     R   -   COO 2 Ca + H 2 O
R   -   COO 2 Ca     CaC O 3 + R   -   COR  
R   -   COOH     CaO   C O 2 + RH
CaO + R   -   COOH     CaC O 3 + RH  
Neutralization reactions take place at a lower temperature, while thermal cracking and catalytic cracking reactions occur at higher temperature [74,107]. Thus, the increase in water content at lower pyrolysis temperatures may be associated with the deoxygenation mechanism [108].
Chen et al. [70] demonstrated that the use of CaO in the pyrolysis of hemicellulose, cellulose, and lignin generates lower amounts of pyrolitic compounds. The authors also mentioned that the CaO could be related to the formation of CO due to the decarbonylation of ketones (linear). In addition, these authors also explain with which compound of the biomass the CaO would react. According to them, the CaO would react with acids/esters and phenols (from hemicellulose). In cellulose, the reaction would be at a low temperature and involve the anhydrosugars, and for lignin, the reaction would occur with the phenols. The effect of the temperature was also analyzed by these authors, and they reported that at high temperatures, to form ketones/furans, the dehydration and ring-opening reaction occurs [70].
Based on experimental evidence, Case et al. [104] proposed that for the pyrolysis of cellulose, one of the proposed pathways is based on the dehydration of sugar intermediates. The authors mention that as a result, it will contribute to the formation of double bonds, that can further follow some radical addition reactions, originating dimethyl- and trimethyl-cyclopentenones [104]. In the analysis of the liquid product generated through the catalytic MAP of BSG using CaO performed in the present study, we found these same compounds.

3. Materials and Methods

3.1. Raw Material

The BSG used in this work was supplied by Abadiana Microbrewery (Minas Gerais, Brazil), which uses 100% malted barley (without the addition of other adjunct materials). The main characteristics of dried BSG are summarized in Table 10.
The chemical composition of BSG was determined using a Perkin Elmer 2400 CHNS/O elemental analyzer operating at 1198 K in an atmosphere of pure oxygen. The oxygen content was calculated by difference considering the C, H, and S wt.% and the ash content. The contents of cellulose, hemicellulose, lignin, and extractives were found following the description used in our previous work [109]. Soxhlet extraction with acetone was used to estimate the extractive content. The lignin content was determined according to modified TAPPI standard T222 om-22 (2002c). Hemicellulose and α-cellulose constitute the holocellulose content, which was measured using glacial acetic acid and sodium hypochlorite at 348 ± 2 K. The α-cellulose was determined by treating the holocellulose sample with potassium hydroxide solutions of 5 and 24% (w/w). The hemicellulose content was calculated subtracting the α-cellulose content from the holocellulose [109].
The BSG showed a high H/C ratio (0.15) and an O/C ratio of 0.80. Thus, BSG has good thermal properties compared to other waste biomass materials, since for pinewood sawdust, the H/C ratio is 0.12, and for wheat stalk, it is 0.14 [110]. For wood sawdust and corn stover, the H/C ratios are both 0.12 [34]. The high quantities of carbon (47.2 ± 1.3 wt.%) are related to the energy value of a fuel because of the energy present in C-C bonds [1]. Furthermore, BSG showed high hemicellulose content compared to other major subcomponents, which offers significant potential for interesting pyrolysis products.

3.2. Microwave-Assisted Pyrolysis

The MAP experiments were carried out in a Menumaster microwave oven (model MCS10TSB, Middleby Brazil, SP, BR) at a maximum incident power of 1500 W and a frequency of 2450 MHz. The schematic diagram of the experimental apparatus is illustrated in Figure 7.
The experimental apparatus consisted of (1) gas sampling—nitrogen, (2) a heating source, (3) a PID temperature controller, (4) a quartz reactor, (5) a microwave oven, (6) a K-type thermocouple, (7) condensers, (8) a thermostatic bath, and (9) a vacuum pump.
Firstly, to determine the influence of moisture content on the results of the microwave-assisted pyrolysis of BSG, 70 g of biomass with different moisture contents was used. After sample preparation, the biomass was placed in the quartz reactor, which was then subjected to microwave radiation using nitrogen as an inert carrier gas at a flow rate of 50 mL/min. In order to maintain an inert atmosphere within the quartz reactor during pyrolysis, the system was vacuumed at 80 mmHg. The experiments were carried out for 30 min. The condensable components (liquid product) were collected in the condensers, while the solid residue in the reactor after pyrolysis was collected as bio-char. The yields of liquid and solid products were calculated on the basis of their actual weight, whilst the gas yield was determined by the difference based on the mass balance, as indicated in Equations (5)–(7):
%   Liquid =   Liquid   Weight Biomass   Weight   × 100
%   Solid = Solid   Weight Biomass   Weight   × 100
%   Gas = 100 - ( %   Liquid + %   Solid )
After the identification of the moisture content of BSG that favored the bio-oil and hydrocarbon yields, a central composite design (CCD) for in situ catalytic pyrolysis was proposed, varying the percentage of catalyst (CaO) and temperature. The same previous conditions of vacuum and inert gas flow were used in these new experiments, in which 70 g of BSG (with the best moisture content identified in the first step) was initially mixed with the corresponding amount of the catalyst until the creation of a homogeneous mixture and then inserted into the reactor.

3.3. Experimental Design

In a first step, a central composite design (CCD) with 2 repetitions at the central point was used to estimate the effects of moisture content ( x 1 in coded values) and temperature ( x 2   in coded values) on the products of MAP of BSG. The dependent output variables were the yields of bio-oil ( y 1 , %), gas fraction ( y 2 , %), and biochar ( y 3 , %) as well as the yield of hydrocarbons present in the bio-oil ( y 4 , %). Table 11 lists the coded ( x i   ) and real values (moisture in % wb and T in °C) of the independent variables. The experimental results were treated using regression techniques. The software Statistica 7.0 was used to analyze the experimental data statistically. The analysis of variance (ANOVA) framework was used to determine the significance of the parameters. A confidence level of 95% was used. The central composite design (CCD), analyzed through this software, is a useful tool to determine the effect of each variable and its interactions. The use of variables in coded levels is an important way that enables the determination of the relative impact of each variable on responses (at the same level range). This helps in the comparison of the intensity of these effects on the desired responses. The coded levels are −α, −1, 0, +1, and +α, in which α is the axial point of 1.414, according to the orthogonal design [16]. The CCD was coupled with response surface methodology (RSM). The RSM technique creates a relationship between the responses and control variables [111].
A second central composite design (CCD) with 2 repetitions at the central point was used to estimate the effects of catalyst/biomass ratios ( x 3 in coded values) and temperature ( x 2   in coded values) on the results of the catalytic microwave-assisted pyrolysis of BSG in an in situ configuration. The dependent output variables were the yields of bio-oil ( y 1 , %), gas fraction ( y 2 , %), and biochar ( y 3 , %) as well as the yield of hydrocarbons present in the bio-oil ( y 4 , %). Table 12 presents the coded and real values of the independent variables.

3.4. Analysis of Products

The chemical compounds of bio-oil were characterized using the methodology described in our previous work [10]. In broad terms, gas chromatography and mass spectrometry were performed using a Shimadzu device (GC/MS-QP2010 Plus, Japan) with a an Rtx-1701 column (60 m × 0.25 mm × 0.25 µm) and helium as a carrier gas. Initially, the GC oven maintained a temperature of 45 °C for 4 min. Then, it reached 270 °C at a rate of 3 °C/min and maintained this temperature for 13 min. The temperature of the injector was 250 °C, and the split ratio was set to 100:1. The MS in electronic impact mode (EI) was operated at a mass range (m/z) of 30–300. The ion source and interface temperatures were maintained at 235 °C for a total run time of 92 min. The data of the main peaks were obtained using retention time (RT) information from the NIST library (version 08). The compounds with a similarity index higher than 80% were identified.
Bio-oil viscosity was measured following ASTM D445 standards using an R/S Plus Rheometer (Brookfield, WI, USA) with an RC3-50-1 spindle at a shear rate of 0–700   s 1 , shear stress of 0–601,603 mPa, time of 200 s, and a temperature of 40 °C. The water content of the bottom phase of the liquid product from the catalytic MAP was determined on a Karl Fischer titrator (Methrom 870 KF Titrino Plus, Germany). Samples of 0.2 g were used for each determination. The measurements were performed in triplicate and the results were expressed as an average.
The surface morphologies of the BSG and the biochar produced in the MAP optimization experiment were analyzed using a ZEISS EVO MA10 scanning microscope. The SEM photographs were captured at 50 and 200× magnification using an electron acceleration voltage of 5.00 kV. The samples were prepared on carbon tabs in an inert environment and coated with gold via sputter coating.

3.5. Catalyst Analysis

The catalyst used in this work was calcium oxide (CaO) (p.a.) in powder form (chemical grade, CAS: 1305-78-8), was purchased from Dinâmica Química Contemporânea LTDA, Indaiatuba, Brazil. This metal oxide was used without any further purification. The XRD analysis of calcium oxide was performed on a SHIMADZU diffractometer (model LABX XRD-6000, Japan). The XRD results were generated in a 2θ interval from 10 to 80° at a step of 0.02° and a scan rate of 2 s per step. The measurements were made using a nickel filter at a voltage of 30 kV and a current of 30 mA.
The thermogravimetric (TG) and differential thermogravimetric (DTG) analyses of the CaO used in this work were obtained using a Shimadzu TGA/DTA analyzer (DTG-60H). The purge gas used was nitrogen at a flow rate of 50 mL   m i n 1 . The experiments were performed with 8 mg of sample from 303 to 1073 K at a heating rate of 5 K m i n 1 . The data were recorded using TG software to yield the mass loss (TG) and differential mass loss (DTG) curves.

4. Conclusions

In this work, the microwave-assisted pyrolysis (MAP) of brewer’s spent grain (BSG), the main waste of the brewing industry, was investigated with the aim of obtaining a liquid product with a high yield and quality.
A high bio-oil yield of 71.8% was obtained with a BSG moisture content of 14%; however, the quality of this product was not so attractive (hydrocarbon yield of 21.60%). In order to improve the bio-oil quality, a catalyst (calcium oxide) was used in the pyrolysis process.
An optimization study was successfully performed, aiming at the simultaneous maximization of the bio-oil yield and quality (hydrocarbon content). The optimum conditions obtained were a temperature at the highest level (570 °C) and a catalyst percentage of 12.17%. The results of the composition of the liquid product under this optimum point using a BSG moisture content of 4% pointed to a liquid yield of 30.88% with a hydrocarbon content of 61.58%. Therefore, it can be concluded that the catalytic MAP process has an enormous potential to transform agro-industrial wastes into high-value products.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/catal13081170/s1, Table S1: % Area from GC/MS results for the liquid product from the CCD runs of the catalytic MAP.

Author Contributions

Conceptualization, F.P. and M.A.S.B.; methodology, F.P. and M.A.S.B.; software, F.P. and M.A.S.B.; validation, M.A.S.B.; formal analysis, F.P. and M.A.S.B.; investigation, F.P., E.F. and Â.D.; resources, M.A.S.B.; writing—original draft preparation, F.P.; writing—review and editing, M.A.S.B.; supervision, M.A.S.B.; project administration, M.A.S.B.; funding acquisition, M.A.S.B. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by CAPES, CNPq, and FAPEMIG.

Data Availability Statement

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Acknowledgments

The authors are grateful to CAPES, CNPq and, FAPEMIG for their financial support.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Response surface of liquid (a) and hydrocarbon (b) yields.
Figure 1. Response surface of liquid (a) and hydrocarbon (b) yields.
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Figure 2. X-ray diffraction analysis of the catalyst.
Figure 2. X-ray diffraction analysis of the catalyst.
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Figure 3. TG and DTG curves of CaO used as metal oxide catalyst (a) prior to experiments (fresh), and (b) after run 6 from the catalytic CCD.
Figure 3. TG and DTG curves of CaO used as metal oxide catalyst (a) prior to experiments (fresh), and (b) after run 6 from the catalytic CCD.
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Figure 4. Catalyst effect on bio-oil quality at 550 °C (the red arrows show the behavior of hydrocarbons and oxygenated after catalytic MAP with different additive ratios of CaO).
Figure 4. Catalyst effect on bio-oil quality at 550 °C (the red arrows show the behavior of hydrocarbons and oxygenated after catalytic MAP with different additive ratios of CaO).
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Figure 5. Response surface of liquid product and hydrocarbon yields.
Figure 5. Response surface of liquid product and hydrocarbon yields.
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Figure 6. SEM micrographs of brewer’s spent grain (BSG) above and the solid products obtained under optimized conditions at 50 and 200× magnification.
Figure 6. SEM micrographs of brewer’s spent grain (BSG) above and the solid products obtained under optimized conditions at 50 and 200× magnification.
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Figure 7. Schematic diagram of the MAP system: (1) gas sampling—nitrogen, (2) heating source, (3) PID controller, (4) quartz reactor, (5) microwave oven, (6) K-type thermocouple, (7) condensers, (8) thermostatic bath, and (9) vacuum pump.
Figure 7. Schematic diagram of the MAP system: (1) gas sampling—nitrogen, (2) heating source, (3) PID controller, (4) quartz reactor, (5) microwave oven, (6) K-type thermocouple, (7) condensers, (8) thermostatic bath, and (9) vacuum pump.
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Table 1. Product yields from the microwave-assisted pyrolysis of BSG.
Table 1. Product yields from the microwave-assisted pyrolysis of BSG.
RunT (°C)MC (%)% Solid% Liquid% Gas *
14505.4334.948.416.7
245012.5723.866.010.2
35505.4343.335.321.4
455012.5717.170.012.9
5430928.656.914.5
6570917.642.440.0
75003.9546.938.414.7
850014.0511.371.916.8
9500923.562.014.5
10500926.164.59.3
* Determined by the difference based on the mass balance (wt.%).
Table 2. GC/MS results obtained from the microwave-assisted pyrolysis of BSG in the first CCD.
Table 2. GC/MS results obtained from the microwave-assisted pyrolysis of BSG in the first CCD.
RunT (°C)MC (%) *% Hydrocarbons% Oxygenated% Nitrogenous
14505.4322.0458.3211.18
245012.5714.3145.977.09
35505.4335.7248.859.04
455012.5717.5158.9611.68
5430911.8350.627.5
6570932.6541.7514.5
75003.9548.8551.150
850014.0521.652.9512.96
9500929.2145.3713.96
10500931.5845.9611.17
* Moisture content of BSG (wt.%).
Table 3. Effects of temperature and moisture content on the liquid and hydrocarbon yield.
Table 3. Effects of temperature and moisture content on the liquid and hydrocarbon yield.
FactorLiquid Product (R2 = 0.97)Hydrocarbon Yield (R2 = 0.89)
EffectStd. Err.p-Value *EffectStd. Err.p-Value *
Mean63.262.09<1 × 10−230.393.91<1 × 10−2
T−3.691.040.025.791.950.04
T2−6.171.380.01−5.662.590.09
MC12.451.04<1 × 10−2−8.051.950.01
MC2−3.411.380.060.832.590.76
T.MC4.301.480.04−2.622.760.39
* Considering the confidence level of 95%.
Table 4. Product yields obtained from the catalytic microwave-assisted pyrolysis of BSG.
Table 4. Product yields obtained from the catalytic microwave-assisted pyrolysis of BSG.
RunT (°C)Cat (%) *% Solid% Liquid% Gas
14501037.6829.8932.43
24502040.6527.7231.63
35501030.0431.7038.28
45502037.7024.9037.40
54301545.2228.9025.88
65701535.3532.8231.83
7500831.5833.8734.55
85002247.8523.8628.29
95001540.6819.9739.35
105001542.4023.3434.26
* Catalyst/biomass ratios.
Table 5. GC/MS results from the catalytic microwave-assisted pyrolysis of BSG.
Table 5. GC/MS results from the catalytic microwave-assisted pyrolysis of BSG.
RunT (°C)Cat (%) *% Hydrocarbons% Oxygenated% Nitrogenous
14501036.6740.8110.21
24502036.8542.318.98
35501052.2726.3611.73
45502054.5824.6010.98
54301535.4542.8310.48
65701553.1626.4011.97
7500846.4532.359.52
85002247.0831.1111.62
95001550.9427.099.65
105001551.2938.509.79
* Catalyst/biomass ratios.
Table 6. Effects of temperature and catalyst on the liquid and hydrocarbon yield.
Table 6. Effects of temperature and catalyst on the liquid and hydrocarbon yield.
FactorLiquid Product (R2 = 0.90)Hydrocarbon Yield (R2 = 0.98)
EffectStd. Err.p-Value *EffectStd. Err.p-Value *
Mean21.651.493<1 × 10−251.111.08<1 × 10−2
T0.560.740.497.290.54<1 × 10−2
T24.270.980.01−3.510.710.01
Cat−2.890.740.010.420.540.47
Cat23.270.980.03−2.280.710.03
T.Cat−1.151.050.330.530.760.52
* Considering the confidence level of 95%.
Table 7. Optimization results: predicted and experimental data from the simultaneous maximization of liquid and hydrocarbon yields.
Table 7. Optimization results: predicted and experimental data from the simultaneous maximization of liquid and hydrocarbon yields.
Coded VariableOriginal FormCoded ValuesUncoded Values
x₂T (°C)1.414570 °C
x₃Cat (%)−0.56512.17%
Yield (%)Predicted ValueExperimental Data *
y 1 (Liquid)32.8730.88
y 4 (Hydrocarbons)53.6761.58
* Experiment performed under these optimum conditions.
Table 8. Compounds in the bio-oil produced in the MAP optimization experiment.
Table 8. Compounds in the bio-oil produced in the MAP optimization experiment.
RT (min)Compound *Formula% Area
25.318UndecaneC11H240.76
11.279TolueneC7H86.28
18.124StyreneC8H84.61
61.528PhenanthreneC14H101.11
17.639OrthoxyleneC₈ H₁₀2.06
14.899NonaneC₉H₂₀0.43
40.262IsopropylmethylnaphthaleneC₁₄H₁₆4.84
26.972IndeneC9H84.35
39.589HexadecaneC₁₆H₃₄5.59
15.706EthylbenzeneC₈H₁₀1.74
30.345DodecaneC₁₂H₂₆0.67
20.087DecanoC₁₀H₂₂0.66
42.442CyclopropylphenylmethaneC₁₀H₁₂0.54
48.224Biphenylene(C₆H₄) ₂2.04
46.711BiphenylC12H100.74
20.499PropylbenzeneC9H120.55
31.043PentylbenzeneC₁₁H₁₆0.78
35.945HexylbenzeneC₁₂H₁₈0.62
25.935butylbenzeneC₁₀H₁₄0.46
23.5702-PropenylbenzeneC₉H₁₀0.81
22.1791-Ethyl-2-MethylbenzeneC₉H₁₂0.53
23.6851-Methyl-3-VinylbenzeneC₉H₁₀0.91
16.1441.3-DimethylbenzeneC₈H₁₀1.97
36,4751,3-DimethylbutylbenzeneC₁₂H₁₈0.52
35.115AzuleneC₁₀H₈8.98
47.9793-OctadeceneC₁₈H₃₆0.39
25.4451-UndeceneC₁₁H₂₂1.46
35.2451-TrideceneC₁₃H₂₆3.22
14.9971-NonenoC₉H₁₈0.54
32.1311-MethylindeneC₁₀H₁₀1.25
30.4771-DodeceneC₁₂H₂₄1.35
20.1961-DeceneC₁₀H₂₀0.82
Hydrocarbons 61.58
16.033PyrroleC₄H₅N1.95
27.497BenzonitrileC₆H₅CN1.35
37.143Benzyl cyanideC₆H₅CH₂CN0.8
39.209IsoquinolineC₉H₇N0.91
46.244IndoleC₈H₇N3.1
49.3381H-Indole, 3-methyl-C₉H₉N0.38
64.417HexadecanenitrileC₁₆H₃₁N1.16
78.132OctadecanamideC₁₈H₃₇NO1.07
Nitrogenated 10.72
31.642PhenolC₆H₆O3.88
33.955Phenol, 2-methyl-C₇H₈O3.75
35.679Phenol, 4-methyl-C₇H₈O4.75
37.857Phenol, 2,3-dimethyl-C₈H₁₀O1.37
43.6892-Methoxy-4-vinylphenolC₉H₁₀O₂3.06
Phenols 16.81
29.8862-Cyclopenten-1-one,2,3-imethyl-C₇H₁₀O0.76
62.5252-Nonadecanone ketonesC₁₉H₃₈O3.05
Ketones 3.81
39.7482-NonenalC₉H₁₆O3.75
Aldehydes 3.73
* Main compounds found in the experiment performed under optimum conditions.
Table 9. Physicochemical properties of the liquid product of some tests of the catalytic MAP of BSG.
Table 9. Physicochemical properties of the liquid product of some tests of the catalytic MAP of BSG.
Physicochemical Properties of the Liquid Product
RunT(°C)Cat (%)Water Content (%)Viscosity (Pa.s)
54301523.85 ± 2.030.01 ± 4.43 × 10 4
65701540.36 ± 2.220.01 ± 1.13 × 10 4
7500849.54 ± 1.750.02 ± 1.78 × 10 4
85002220.04 ± 1.360.01 ± 1.94 × 10 4
105001566.41 ± 3.70 0.02 ± 2.16 × 10 5
Table 10. Characteristics of brewer’s spent grain (BSG).
Table 10. Characteristics of brewer’s spent grain (BSG).
Proximate Analysis (wt.%)
HHV (MJ/kg) *17.94 ± 3.74
Moisture3.7 ± 0.35
Volatile matter82.25 ± 0.03
Ash3.19 ± 0.07
Fixed carbon14.55 ± 0.03
Ultimate Analysis (wt.%)
C47.2 ± 1.3
H7.2 ± 0.1
N3.6 ± 0.4
S1.1 ± 0.1
O37.6 ± 1.7
Chemical Composition (wt.%)
Extractives5.26 ± 0.06
Lignin29.37 ± 4.03
Cellulose15.14 ± 0.03
Hemicellulose50.23 ± 0.03
* HHV is the higher heating value.
Table 11. Coded and real values of the independent variables in the first central composite design.
Table 11. Coded and real values of the independent variables in the first central composite design.
VariablesLevels *
Coded values ( x 1 and x 2   )−1.414−10+1+1.414
Moisture content (% wb)3.955.43912.5714.05
Temperature (°C)430450500550570
* Determined for the central composite design (CCD).
Table 12. Coded and real values of the independent variables in the second central composite design for the catalytic MAP of BSG.
Table 12. Coded and real values of the independent variables in the second central composite design for the catalytic MAP of BSG.
VariablesLevels
Coded values ( x 3 and x 2   )−1.414−10+1+1.414
Catalyst (% Cat) *810152022
Temperature (°C)430450500550570
* Catalyst/biomass ratios.
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Pimenta, F.; Filho, E.; Diniz, Â.; Barrozo, M.A.S. Catalytic Microwave-Assisted Pyrolysis of the Main Residue of the Brewing Industry. Catalysts 2023, 13, 1170. https://doi.org/10.3390/catal13081170

AMA Style

Pimenta F, Filho E, Diniz Â, Barrozo MAS. Catalytic Microwave-Assisted Pyrolysis of the Main Residue of the Brewing Industry. Catalysts. 2023; 13(8):1170. https://doi.org/10.3390/catal13081170

Chicago/Turabian Style

Pimenta, Fernanda, Elmis Filho, Ângelo Diniz, and Marcos A. S. Barrozo. 2023. "Catalytic Microwave-Assisted Pyrolysis of the Main Residue of the Brewing Industry" Catalysts 13, no. 8: 1170. https://doi.org/10.3390/catal13081170

APA Style

Pimenta, F., Filho, E., Diniz, Â., & Barrozo, M. A. S. (2023). Catalytic Microwave-Assisted Pyrolysis of the Main Residue of the Brewing Industry. Catalysts, 13(8), 1170. https://doi.org/10.3390/catal13081170

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