1. Introduction

At the moment, energy carriers used for transport are mainly derived from oil. This leads to a reduction in natural fuel resources and the emission of greenhouse gases in significant quantities [1,2,3,4]. Europe aims to be the first climate-neutral continent by making its economy modern and resource-efficient. For that reason, the European Union has been supporting the development of renewable energy sources, including biofuels, wind, water, and solar energy, for many years [5]. The biofuel economy in Poland has been in development since around 2000. Ethanol and esters have similar properties to commonly used fuels (ethanol and biodiesel), but the major difference between biofuels and petroleum-based fuels lies in the content of oxygen [6]. Biofuels contain 10–45% oxygen by weight, whereas petroleum-based fuels have basically no oxygen, meaning that biofuel molecules have fewer carbon atoms than those of petroleum, which makes them less calorific. Naturally, liquid biofuels have a higher oxygen content, due to their chemical structure—they are esters of alcohols and higher fatty acids [7]. According to the scientific papers, this difference can be regarded as the most significant. Two liquid biofuels are currently in use in Poland: (i) ethanol, which can substitute petrol; and (ii) biodiesel, used as a diesel additive. Five per cent of ethanol is added to petrol and seven per cent of methyl esters are added to diesel. This is related to the promotion of renewable energy sources and to the reduction in carbon dioxide emissions from fossil fuels, which negatively affect the environment. Emitted into the atmosphere, carbon dioxide is responsible for exacerbating the global greenhouse effect [8].

In Poland, the main raw material for the production of ethanol for energy purposes is maize grains. The maize grown nowadays is one of the most efficient crops in the world. Its yield is associated with many factors, the most important of which include weather patterns, crop variety, growing position, and agrotechnical treatment [9,10]. The vegetation period has a major impact on potential yield. In Poland, there are three vegetation period groups described by the FAO number (Food and Agriculture Organization of the United Nations), which is the international index of the development of maize varieties. In Poland, the FAO number for maize varieties is determined by the Research Centre for Cultivar Testing (COBORU). These vegetation period groups are as follows: medium-late (FAO above 260), medium-early (FAO 240–250), and early (FAO up to 230). According to official COBORU data, in 2019–2020 early grain maize varieties yielded an average of 100.0 [dt-ha⁻¹] (14% of humidity); mid-early varieties yielded an average of 99.9 [dt-ha⁻¹] (14% of humidity); and mid-late varieties yielded around 100.1 [dt-ha⁻¹] (14% of humidity). The average yield from the three varieties of vegetation periods is 99.98 [dt-ha⁻¹], which equals 9.998 [Mg·ha⁻¹]. As a plant, maize has many applications. It is used as animal feed, for the production of biofuel (as already mentioned), and sweetcorn is grown for human consumption. In biofuel production, the whole plant (in the form of maize silage) can be utilised in biogas production processes, and maize grains alone can be used in technologies for obtaining ethanol [11,12]. Maize ears, stalks, and leaves can be processed into fermentable sugars through cellulose-processing technology, which involves pretreatment, hydrolysis, and fermentation involving yeast or other microorganisms. As opposed to cereal feedstocks, the production of cellulose-based ethanol requires microorganisms capable of synthesising ethanol from both glucose and xylose. Maize grains contain large amounts of starch, which is easily converted to monosaccharides after pretreatment (i.e., cooking in water) and the hydrolysis process [13]. The process of producing ethanol from maize has already been consolidated in various countries. The inclusion of this feedstock into the system of production, as pointed out by Brazilian researchers, will add value to the product and contribute to the stabilisation of the ethanol supply in the country [14].

1.1. Maize Ethanol Production

The production of ethanol from maize involves the decomposition of the starch contained in maize grains to glucose (C₆H₁₂O₆) and maltose (C₁₂H₂₂O₁₁). Subsequently, both sugars are broken down through alcoholic fermentation to ethanol (see Equation (1)). Starch is a chemical compound consisting exclusively of glucose structural units linked by α-glycosidic bonds and hydrolyses only into α-D-glucose. However, it is not a chemically homogeneous compound—it consists of two polymeric fractions: branched chains of amylopectin, containing α-1,4 and α-1,6-glycosidic bonds, and a linear polymer with α-1,4-glycosidic bonds of amylose [14]. During the process of ethanol production, the starch structure is destroyed by enzymes and high temperatures. Even though starch exhibits hydrophobic properties, it dissolves in water when heated, which results in the weakening of the hydrogen bonds. As a result, the starch increases in volume; this stage is known as the gelation process. Due to the heat treatment and the enzymes involved, the starch decomposes into glucose. At the first stage (hydrolysis), α-amylase reduces the polymer chains of starch to dextrins; this process is called liquefaction. The dextrins are then degraded (saccharified) to glucose and maltose in the presence of the glucosamine enzyme [15]. The resulting product is subjected to alcoholic fermentation, resulting in the extraction of ethanol and a by-product, the digestate pulp, which contains chemical compounds that will not convert to ethanol.

Equation (1) illustrates the starch decomposition reaction in the alcoholic fermentation process [16]:

3C₆H₁₀O₅ + 3H₂O → C₆H₁₂O₆ + C₁₂H₂₂O₁₁ + H₂O→ 6C₂H₅OH + 6CO₂(1)

When it comes to ethanol production, the by-product is stillage, which constitutes a problematic waste product. This material can be used as a substrate for the production of biogas in the process of methane fermentation. Both worldwide and in Poland, there are installations in which ethanol is produced and the digestate is used as a substrate in a biogas plant. Such solutions result in the optimal use of the energy potential of maize grain fuel to produce the maximum number of energy carriers from renewable energy sources.

1.2. Biogas Production

Anaerobic technologies have considerable potential in the management of a wide range of organic wastes [17,18,19]. These wastes most often include waste from animal production, such as manure and slurry, and purpose-grown crops, mainly maize for silage production, but also sewage sludge and food-industry waste [20,21,22]. In the absence of oxygen, gas is generated from organic biomass containing proteins, fats, and sugars [23]. This gas is defined as biogas due to its origin and generation process, determined by the activity of living micro-organisms. Its main components include methane and carbon dioxide, together accounting for about 95–99% of the mixture [24,25]. Other gases, contained in biogas in small quantities, include hydrogen, ammonia, and hydrogen sulphide. Biogas can be continuously generated under suitable environmental conditions that are friendly to the perpetual recreation of the methane-forming bacterial flora. Its composition and quantity depend on the parameters of the environment in which it is produced [26,27]. Essentially, the anaerobic digestion process can be divided into four phases: hydrolysis, acidogenesis, acetogenesis, and methanogenesis. A characteristic group of microorganisms, requiring specific environmental conditions, are responsible for each respective cycle [28,29]. This process is usually conducted in a one- or two-stage system involving two fermentation tanks. To conduct anaerobic digestion effectively and maximise the production potential of individual bacterial groups, it is necessary to prepare appropriate feed material and environmental conditions [30,31,32]. During the production of energy carriers from renewable sources, it is worth introducing integrated technologies to improve the efficiency of biomass conversion from the organic matter contained in it.

The stillage obtained in ethanol plants can be further processed in biogas plants because it contains a certain amount of organic matter from which biogas can be generated (see Figure 1). The aforementioned material contains compounds—mainly lignocelluloses, which can serve as a raw material for the production of biogas through anaerobic digestion [33]. Therefore, the waste product from the first process (stillage) can function as the raw material for a second process (the production of biogas). In their study, Lanzerstorfer and Jäger (2008) identified three main correlations between the processes of bioethanol and biogas production: (i) low-temperature energy is used for heating purposes in the production of bioethanol at the fermentation stage, (ii) high-temperature energy from the cogeneration of waste gas is used to produce steam for the distillation stage in bioethanol production, and (iii) the distillery stillage is used as a raw material for biogas production [34]. However, the industrial-scale application of this solution is often considered groundless, due to its low economic competitiveness in comparison with the production of energy from fossil fuels. These limitations are based on the high-energy requirements associated with the treatment of biomass before the fermentation stage and with the management of stillage. In their study, Cesaro and Belgiorno (2015) regarded the combination of bioethanol production and anaerobic digestion as a valuable option that can overcome any limitations, such as those related to the pretreatment of biomass or the management of stillage [35]. Furthermore, the experimental results obtained by the authors revealed that fermentation acts as a pre-treatment of the biomass so that the energy needed to convert stillage into biogas in the anaerobic digestion process is lower than the energy needed to process the entire substrate. It has been unambiguously established that a synergistic combination of alcoholic fermentation and anaerobic digestion can enable the production of ethanol together with biogas, which can be used to produce heat and electricity (see Figure 1—cogeneration aggregate), thus improving the overall energy balance. Martin et al. also draw similar conclusions in their publication (2014) [36]. The findings of the studies conducted within this concept demonstrate how important it is to understand the impact of biofuel production and industrial symbiosis and how valuable the different flows of matter and energy are. The concept of utilising waste biomass in a sequential combination of two biochemical processes, ethanol fermentation and methane fermentation, can also offer specific environmental protection benefits, such as the utilisation of waste from the agricultural sector, a reduction in organic contaminants, and a reduction in dust and gas emissions from the combustion of conventional energy sources [37]. It is rightly assumed that symbiotic activities can lead to benefits regarding environmental performance, although the choice of impact category and allocation method is crucial when comparing local versus global impacts [36].

This study aimed to determine the energy potential of biomass used for bioethanol and biogas production. Based on the results obtained, the conversion rate of biomass—maize in this case—into bioethanol was determined as the efficiency of the bioethanol production process. At the next stage, it was possible to identify the unused biomass energy potential accumulated in the waste material in the form of stillage. The degree of the conversion of biomass to bioethanol and the susceptibility of biomass to conversion into biogas was therefore determined. The possibility to estimate the insufficient conversion of biomass allows the production of energy carriers from renewable raw materials to be optimised.

2. Materials and Methods

2.1. Physicochemical Analysis of Materials

Physicochemical analyses of substrates and samples were performed with the use of the methods and procedures described in the following standards: pH—potentiometric analysis, with Elmetron CP-215, Zabrze, Poland (PN-EN 12176:2004); total solids (residue after drying)—gravimetric analysis, measurement by drying at 105 °C (Zalmed SML dryer, Zalmed, Łomianki, Poland), PN-EN 12880: 2004; volatile solids (residue after roasting)—gravimetric analysis, measurement by combustion at 550 °C (MS Spectrum PAF 110/6 furnace, MS Spectrum, Warsaw, Poland), PN-EN 12879:2004; sample collection for chemical and physical tests, PN-EN ISO 5667-13:2011; carbon, EN ISO 16948:2015; hydrogen, EN ISO 16948:2015; nitrogen, EN ISO 16948:2015; oxygen, based on calculations; sulphur, PN-EN ISO 11885:2009.

The quantitative determination of the chemical composition of maize grains, i.e., starch, total dietary fibre, mineral matter (insoluble ash), fat, and protein was performed according to the following procedures:

• Starch—Luff–Schoorl titration method, range: (0.50–80)%; reduction in Cu(II) ions in the Luff solution (sodium carbonate, citric acid, copper sulphate) by reducing sugars, boiling point, pH approx. 9.5 [38];

• Fibre—chemical method (fibre is determined as the fraction remaining after digestion with standard solutions of 0.25 N sulphuric acid and 0.25 N sodium hydroxide under carefully controlled conditions) AOAC 962.09 [39];

• Fat—Soxhlet method, extracted with hexane using a Soxhlet automatic extractor, model B-811 BUCHI, (Büchi Labortechnik AG, Flawil, Switzerland); AOAC 920.85 [40];

• Protein—calculated from TKN (total Kjeldahl nitrogen) using a conversion factor of 6.25 for crude proteins; AOAC 920.87 [41]; TKN—titration, Kjeldahl method, 0.1 n HCl, Tashiro’s indicator; PN-EN 13342, EN 15104:2011;

• Mineral matter—ash, range: (0.02–40%), gravimetric analysis [42].

To determine the elemental composition of maize grains, the elemental analysis of elements C, H, N, S, and O was performed using the CHNSO FlashSmart series elemental analyser obtained from Thermo Fisher Scientific (Waltham, MA, USA), which is Organic Elemental Analysis (OEA) equipment. The device uses the method of the dynamic combustion of samples (of both organic and inorganic origin) in a reactor filled with an oxidation-reduction catalytic bed, with the electronically controlled temperature reaching 1800 degrees Celsius (CHNS analyses) or in a pyrolytic reactor (O analyses). The analyser works by separating combustion gases on a chromatographic pillar and then detecting them on a highly sensitive thermoconductivity detector.

2.2. Laboratory Scale

The anaerobic digestion process was conducted in a periodic mode of operation of the digesters, under mesophilic conditions. The authors of this study presented a detailed diagram and described the design and operation of biodigesters in their previous publications (Figure 2) [43,44].

According to the German standard DIN Guideline 38 414-S8 (DIN, Deutsches Institut für Normung) [45], the experiment was conducted until the daily biogas production in all biofermenters decreased below 1% of the total biogas production. The volume of biogas, which was generated using the laboratory scale from stillage, was measured every 24 h. The concentrations of methane, carbon dioxide, hydrogen sulphide, ammonia, and oxygen in the biogas were measured using a Geotech GA5000 gas analyser (Geotech, Bydgoszcz, Poland).

The estimation of the biogas efficiency (in m³·Mg⁻¹) from dry matter or dry organic matter was based on experimental data. The biogas efficiency for a given substrate was determined by subtracting the amount of biogas produced from the inoculum alone (obtained in the control test) from the amount of biogas produced for the mixture (substrate/inoculum). For bioreactors with a substrate or mixture of substrates tested, the cumulative amount of biogas produced from the inoculum (digested sewage sludge) was calculated based on the corresponding equation presented in other publications of the authors [21,22,23,24]. Specific biogas production from the substrate (dependent on the duration of the test) was calculated in stages—from one reading to another [21,22,23,24].

2.3. Construction and Operation of an Industrial Installation

The biomass conversion study was conducted for 12 months in a biogas plant that used stillage derived from bioethanol produced in a Polish distillery (the exact location is not given at the request of the owner). Stillage samples were collected at quarterly intervals for accurate stillage analysis. The biogas plant (also in Poland) consisted of 2 digesters and a lagoon for digestate. The anaerobic digestion process was conducted simultaneously in both tanks, without division into primary and secondary digestion. The installation was equipped with a 1 MWe cogeneration plant.

2.4. Collection of Samples for Tests

Samples for testing both maize grains and the stillage were collected every quarter (QU-I, QU-II, QU-III, QU-IV; QU—quarter). During sample collection, the following points were taken into account: the accessibility of the sampling point, the possibility of a safe interruption of the material flow in case of manual sampling, and the type of digester design due to the stratification of the test material. In addition, the safest and most practical position for manual sampling was analysed and the practicality of the location of the sampling site was considered due to the crucial role and representativeness of the material collected for testing. At least 3 samples were collected and tested each time to increase confidence in the representativeness of the material collected. The material analysed for representativeness was then subjected to testing. Based on the analyses performed, the uncertainty of the results was also determined.

Measurement uncertainty is a component of the individual stages of the analytical procedure. Uncertainty is a fundamental property of any measurement and it is encountered at every stage of the measurement procedure. The measurement uncertainty estimation in this study employed procedures in line with standards and literature data [46,47].

2.5. Determination of the Biochemical Methane Potential Correction Coefficient (BMPCC)

Due to the lack of reliable data in the source literature regarding biomass conversion on a technical scale, the authors developed and applied the Biochemical Methane Potential Correction Coefficient (BMPCC) in their previous paper [48]. The coefficient can be used to verify the operation of the installation in terms of the decomposition of organic matter into methane as compared to laboratory conditions. With the application of chemical formulae and laboratory tests, the potential amount of methane from the substrate can be determined, allowing for a more accurate analysis of the installation’s efficiency on a technical scale. Consequently, this parameter acts as a diagnostic tool for a biogas installation over a specific time interval.

To calculate the BMPCC, it is necessary to determine the values of relevant parameters, according to the coefficient formula (Equation (4)). In the first phase, the amount of biogas obtained from the substrate (m³·Mg⁻¹ fresh matter (FM)) was estimated in the laboratory [43]. At the same time, the biogas composition was analysed in order to determine the CH₄ and CO₂ concentrations. After determining the composition of the biogas, the process proceeded to the calculation of the volume of methane. Subsequently, the mass of methane contained in the biogas was determined under laboratory conditions (mass of methane in biogas obtained from fresh substrate matter under laboratory conditions, MMB-L; L—laboratory). The third stage involved the analysis of the substrate for dry residue, roasting losses, and the content of carbon, hydrogen, oxygen, nitrogen, and sulphur. Once the content of C, H, O, N and S was determined, the theoretically obtainable amount of methane (theoretical methane mass, TMM) was calculated according to the principle of mass conservation. It was followed by the fourth stage, in which the conversion of organic matter contained in biomass under laboratory conditions was calculated (conversion of organic matter under laboratory conditions—laboratory biomass conversion degree, COM-L). Equation (2) is as follows [48]:

(2)$\mathrm{COM}-\mathrm{L}=\frac{\mathrm{MMB}-\mathrm{L}}{\mathrm{TMM}}$

The next stage involved the calculation of the conversion of organic matter contained in the biomass under the operating conditions of the installation (conversion of organic matter in the installation—industrial biomass conversion stage, COM-I; I—industrial) [41]. Equation (3) is as follows [48]:

(3)$\mathrm{COM}-\mathrm{I}=\frac{\mathrm{MMB}-\mathrm{I}}{\mathrm{TMM}}$

The final stage of the process was to calculate the BMPCC of each substrate as the ratio of the mass of methane produced in the installation to the mass of methane produced under laboratory conditions. Equation (4) is as follows [48]:

(4)$\mathrm{BMPCC}=100-\frac{\mathrm{COM}-\mathrm{I}}{\mathrm{COM}-\mathrm{L}}\times 100$

3. Results and Discussion

3.1. Elemental Analysis of Maize Grains

The starting point for the calculations made in this study was the analysis of the percentage content of chemical compounds in the maize grain, which acts as a substrate in a distillery (see Figure 3). Grain analysis was performed quarterly; four consecutive periods yielded very similar grain chemistry results, allowing them to be averaged. For the values shown in Figure 3, the uncertainties of the results were ±1.9 for starch, ±0.34 for fibre, ±0.042 for mineral matter, ±0.21 for fat, and ±0.24 for protein (amino acids).

Next, based on the elemental analyses of the maize grain sampled in each quarter, the elementary formulae were determined, and are presented in Table 1.

Table 2 shows the molar mass of the individual elements that constitute the chemical compounds that make up the maize grain and the intermediate compounds in the alcoholic fermentation process (glucose and maltose). The presented data show that the C:H:O ratio is similar.

3.2. Volume of Ethanol Obtained from One Tonne of Maize Grain in the Analysed Installation

According to different authors, between 340 and 410 L of ethanol can be obtained from 1 Mg of maize grain [49,50]. In the analysed installation, which is located in Poland, one Mg of maize grain yielded, as shown in Table 3, between 342 (QU-II) and 370 (QU-I) litres of ethanol, expressed by 100% ethanol of 0.7893 g·mL⁻¹ density, which confirms the literature data [51,52].

According to Milanez et al. [53], the cycle of corn production is four months long, has the advantage of storing grain, and also off-season maize production. As noted by Quintera et al., (2008), compared to sugarcane ethanol, corn ethanol has some manufacturing defects, but corn uses less water (mm) in its harvest cycle, and the harvesting cost is lower [54] In addition, maize grains contain more starch than, for example, potatoes or rye [55,56]. Regarded as the greatest energy source in cereals [57], for this reason, corn is the primary material in Poland for the production of ethanol for energy purposes. Amylose (15–25%) and amylopectin (75–85%) are the two polysaccharides that comprise starch [58]. Amylose is essentially linear and made up of D-glucose molecules of alpha-1,4 bonds, whereas amylopectin is a highly branched macromolecule consisting of short chains of D-glucose with alpha-1,4 bonds and 1,6 branching points. Corn starch contains approximately 25–28% amylose, which affects the structural characteristics of the starch—due to the linearity of its chemical chain, it ensures granule resistance [59].

Table 4 shows the basic parameters of the maize grain samples for each quarter. According to the data, throughout the entire study period, the percentage content of total solids was similar and ranged between 84.9% for QU-IV and 86.2% for QU-I. The value of volatile solids was also similar for individual samples and ranged between 97.9% for QU-IV and 98.6% for QU-III.

Table 5 shows the percentage content of elements in relation to their mass in each molecule. The highest carbon content was found in maize grain (from quarters QU-I, QU-II, QU-III, and QU-IV) due to the presence of lignin, fat, and protein. On the other hand, as shown in Table 5, the grain contains proportionally fewer oxygen atoms per molecule compared to starch. Starch in maize grain breaks down into glucose and maltose during the process of alcoholic fermentation. In contrast, the other compounds are inert and do not participate directly in the process. However, because of temperature (mainly lignin) and some random processes, particularly those that disrupt the alcoholic fermentation process, their structure can be completely or partially destroyed due to the activity of competing microorganisms. In the process of obtaining ethanol, the chemical compounds that do not participate in the process penetrate the stillage and provide a potential source of energy for subsequent stages of biomass utilisation. The results presented in Table 5 are juxtaposed to illustrate the energy potential of maize grain as compared to starch as the main chemical compound responsible for the alcoholic fermentation process efficiency.

The average yield of pure 100% ethanol from an Mg of maize grain can be used to determine how much organic matter was converted into ethanol. Table 6 presents the conversion of organic matter subjected to alcoholic fermentation, including a calculation of the mass of each chemical compound.

The conceptual reaction for obtaining ethanol is as follows [60] (Equation (5)):

C₆H₁₂O₆ → 2C₂H₅OH + 2CO₂(5)

During the alcoholic fermentation process, the starch contained in the maize grain has an overarching impact on the amount of bioethanol obtained [61,62]. Nonetheless, this process can be disrupted by infection with viruses or bacteria that will compete for nourishment with the right microorganisms responsible for the actual process of alcoholic fermentation. The data presented in Table 6 reveal that the most effective bioethanol production process took place in QU-IV, where the percentage of non-converted mass was the lowest, reaching 32.37%. The lowest degree of organic matter reactivity (528.14 kg) was recorded in QU-II, where the degree of non-reactivity was 36.95%.

3.3. Analysis of Digestate Pulp from Bioethanol Production in a Biogas Plant—Tests in the Laboratory and on a Technical Scale

The stillage derived from the production of bioethanol was subjected to laboratory-scale testing of their biochemical methanogenic potential. For each tonne of maize grain processed, the analysed industrial plant produces an average of 5 m³ of stillage, which is used as a raw material to feed the biogas plant. The capacity of the biogas plant, which remains in research-based cooperation during this experiment, amounts to 1 MW_e. Table 7 lists the basic stillage parameters. Figure 4 and Figure 5 present the volume of biogas obtained and the concentration of biogas methane from 1 Mg _FM (FM—fresh matter) of the stillage.

Figure 4 and Figure 5 present the results concerning the amount of biogas obtained (Figure 4), including methane (Figure 5), under laboratory and technical conditions. The highest biogas yield was obtained in QU – n II, exceeding 35.6 m³·Mg _FM⁻¹ on the laboratory scale and 33.2 m³·Mg _FM⁻¹ on the technical scale. In contrast, the lowest biogas volumes were obtained in QU-I—in total, 30.5 m³·Mg _FM⁻¹ was obtained on the laboratory scale and 29.2 m³·Mg _FM⁻¹ on the technical scale. The methane content in biogas ranged from 50.1% in QU-I to 50.9% in QU-III. Remarkably similar methane contents in biogas point to a stable anaerobic digestion process and high repeatability of the quality composition of the stillage that was fed in. The differences in the amount of biogas volume obtained, on the other hand, are mainly related to the quality of the alcoholic fermentation process, which directly affects the content of organic matter (in the stillage), which is a nutrient substance for anaerobic digestion bacteria [63]. It serves as the confirmation that these processes function in an integrated manner and remain in industrial symbiosis with each other [64,65] to comprehensively utilise organic matter for energy purposes. A full understanding of the mechanism of this concept provides an opportunity to undertake process optimisation in accordance with the technological principle of using the raw material and the energy stored in it most effectively.

3.4. Conversion of the Organic Matter Contained in the Stillage

Figure 4 and Figure 5 were used to determine the mass of methane in the biogas obtained from the fresh matter of the substrate under laboratory conditions (MMB-L, see Section 2.5). Then, the principle of mass conservation (stoichiometric Equation (6)) was applied to calculate how much methane can theoretically be obtained when the values of C, H, O, N, and S are known, i.e., the theoretical methane mass (TMM) based on elementary chemical formulae.

C_cH_hO_oN_nS_s + yH₂O → xCH₄ + (c − x)CO₂ + nNH₃ + sH₂S(6)

Further, the conversion of organic matter to methane was determined (see Figure 6) both on the laboratory and technical scales (Equations (2) and (3)). Under laboratory conditions, higher biomass conversion rates were observed for each period compared to the technical scale. The poorest biomass decomposition occurred during QU-III and the best decomposition took place in QU-II and QU-IV under laboratory conditions.

In the literature on the subject, there is a clear lack of information addressing the underestimation of biomass conversion under actual conditions when compared to laboratory conditions. The lack of knowledge in this regard can have a negative impact on the economic balance of the entire process that is conducted on a real scale. The integrated production of bioethanol and biogas presented in the literature mainly concerns the implementation of processes on a laboratory scale, which, in turn, can only serve as a model [36,37]. Only a few publications highlight the fact that hybrid biomass conversion in combined technologies is very much needed and warranted, and they do not explain what this need results from.

Based on the data presented above (Figure 6), it was possible to calculate the Biochemical Methane Potential Correction Coefficient (BMPCC, Equation (4)), the values of which are presented in Figure 7. With the BMPCC, it was possible to identify the quarter in which the anaerobic digestion process on the technical scale deviated from the same process under laboratory conditions. At the same time, information was acquired on the extent to which biomass did not convert. It was found that biomass in QU-II had the weakest degree of degradation, while biomass in QU-IV had the greatest—on the technical scale, as compared to the laboratory scale. As previously mentioned, the BMPCC can serve as a diagnostic parameter to determine the condition of a biogas installation over a specific time interval [48].

In conclusion, the integrated production of bioethanol and biogas is an example of industrial symbiosis—which, taking into account both environmental and economic needs related to the emission of greenhouse gases, the diversification of biofuel production, the creation of conditions for self-sufficiency, and the stimulation of economic development—positively influences the efficiency of technological processes (optimisation of materials and energy). It is worth mentioning that there are several examples of the biofuel industry effectively using by-products in further applications, due to their organic makeup. In addition to the previously discussed use of ethanol byproducts for biogas production, other applications include the use of glycerol from biodiesel production for biogas production, the use of digestate from biogas plants as a fertilizer, and the use of sewage treatment byproduct (sewage sludge) as a substrate in biogas plants (preferably adjacent to sewage treatment plants) [21,24,36].

Publications related to the topic of the integrated production of bioethanol and biogas mainly address: (i) local and global symbiotic activities (potential acidification and eutrophication due to system expansion, and global benefits); (ii) maize pretreatment methods (improving access to cellulose in maize silage and extracting hemicellulose sugars from maize silage fibres by, e.g., steam pretreatment, with or without a catalyst) that increase the efficiency of ethanol production [66,67]; and (iii) applications of new, interesting raw biomaterials for bioethanol and biogas production—such as a species of wild inedible cassava, Manihot glaziovii (tubers obtained from three different areas in Tanzania) [68]—a general evaluation of the efficiency of the process [65,69], and its economic aspects [70]. As previously mentioned, the efficiency scores of the bioethanol production process, including methane, quoted from other papers are comparable to those presented in this study. However, authors have often indicated that higher energy efficiency options (e.g., due to the processing methods applied) did not necessarily result in lower ethanol production costs. Yet, these works lack information addressing the underestimation of biomass conversion under actual conditions when compared to laboratory conditions.

4. Conclusions

The integrated production of bioethanol and biogas makes it possible to optimise the production of carriers from renewable raw materials. The organic matter subjected to alcoholic fermentation yielded between 342 L (QU-II) and 370 L (QU-I) of ethanol, expressed by 100% ethanol of 0.7893 g·mL⁻¹ density. The mass that did not undergo conversion to bioethanol ranged from 269.04 kg to 309.50 kg, representing 32.07% to 36.95% of the organic matter processed to produce bioethanol. With this in mind, it was concluded that only two-thirds of the organic matter was converted into bioethanol. The remaining part, as post-production waste in the form of stillage, became a valuable raw material for the production of biogas, containing one-third of the biodegradable fraction.

The installation analysed in this experimental paper was a hybrid system, in which waste from bioethanol production was used in a biogas plant with a capacity of 1 MW_e. Under laboratory conditions, the organic material, derived from stillage and subjected to anaerobic digestion, yielded between 30.5 m³ (QU-I) and 35.6 m³ (QU-II) of biogas per 1 Mg _FM. On the other hand, under operating conditions, between 29.2 m³ (QU-I) and 33.2 m³ (QU-II) was obtained from 1 Mg _FM, which directly translated to the degree of conversion of biomass to biogas, including methane—the energy carrier. The content of methane in the biogas produced on a technical scale was also lower than under laboratory conditions. For this reason, it is important for biogas plant owners to be able to estimate the insufficient conversion of biomass in their plants.

The Biochemical Methane Potential Correction Coefficient (BMPCC), which was developed in an earlier paper by the authors, made it possible to determine the difference between the efficiencies of the anaerobic digestion processes occurring in the installation and in the laboratory (as the ratio between the mass of methane produced in the installation and the mass of methane produced under laboratory conditions). With these calculations, it is possible to carry out a thorough analysis of the process implemented in a given plant and obtain clear information on the direction of solutions to improve installation efficiency. In the biogas installation analysed in this paper, the BMPCC ranged between 3.2% and 7.4%, which is indicative of the efficient conversion of biomass to biogas on a real scale. Biomass subjected to the process of anaerobic digestion is more susceptible to decomposition during anaerobic digestion.

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Figure 1. Conceptual scheme of integrated bioethanol and biogas production (authors’ own scheme).

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Figure 2. Anaerobic bioreactor used in biogas production experiment: 1—water heater; 2—water pump; 3—insulated tubes for heating medium; 4—water jacket (39 °C); 5—bioreactor (1.4 L); 6—slurry sampling valve; 7—tube for biogas transport; 8—graduated tank for biogas; 9—gas sampling valve (authors’ own elaboration).

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Figure 3. Chemical composition of maize grain (authors’ own elaboration).

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Figure 4. Volume of biogas obtained from m3·Mg FM−1 (L—laboratory scale; T—technical scale).

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Figure 5. Methane percentage in biogas (L—laboratory scale; T—technical scale).

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Figure 6. Biomass conversion degree (L—laboratory scale; T—technical scale).

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Figure 7. Biochemical Methane Potential Correction Coefficient (BMPCC) for individual quarters.

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