Residual Biomass Recovery in the Wine Sector: Creation of Value Chains for Vine Pruning

Abstract

Waste management is a current and transversal problem in all production areas, including agriculture. Within this economic activity, wine production generates a large amount of waste, namely, that resulting from the winemaking activity itself, such as pomace and grape stalks, and waste resulting from the management of the vineyards, with operations such as vine pruning. The management of vine pruning residuals has traditionally been conducted by burning leftovers on-site, without any use for the energy produced. This research analyzed the potential for the valorization of residual biomass resulting from vine pruning by creating a business model based on value chains of local scale. For this analysis, several samples of residues resulting from the “Loureiro” vine variety planted in Ponte de Lima (northern Portugal) were collected and characterized. The objective of the small-scale business model created, in addition, to solving the environmental problems related to the disposal of waste from agricultural activities, a value chain can be established, contributing to increasing the income of the farmers while introducing a circular bioeconomy and sustainable rural development practices.

1. Introduction

The increasing demand for food products and other basic resources by a growing population has led to the intensification of agricultural and industrial activities [1]. Several studies have focused on this topic, highlighting the issue of waste products as a result of this intensification of agricultural and industrial activity, and its subsequent consumption [2,3,4]. Tripathi et al. stated that agricultural waste is a burgeoning problem because their disposal, utilization and management practices are not efficiently or universally applied [5]. It is, therefore, a problem that can even exacerbate the worse consequences of the practices traditionally in use in the regions where these residues are produced. The same authors mentioned that, in many countries and regions, the current practices consist of these wastes being left in the fields to decompose or be burnt, resulting in significant environmental impacts, without any compensation for the release of greenhouse gases. In this way, all the practices that can contribute to avoiding the continuation of these traditional methods help to mitigate the negative impacts resulting from less sustainable waste from agricultural activity management practices [6,7,8].

Over time, with technological evolutions, several methods have been applied as a way of valuing residual biomass [9]. The success rate of these practices is closely related, firstly, to the degree of maturity of the technologies used, which, due to the fact of them being more or less robust, may allow greater efficiency in the waste disposal process, and, secondly, to the heterogeneity of the waste to be processed [10]. Biomass waste, whether being of agricultural origin, from forest management operations, or even from the organic fraction of urban waste, has such a great diversity that its management using a single process becomes very difficult [11,12]. In this way, for example, processes such as anaerobic digestion are very efficient for the recovery of residues rich in cellulosic materials, whereas on the other hand, fermentation is more efficient when the residues have a large amount of carbon hydrates [13,14]. However, none of these processes are efficient when the residues are rich in lignin, as is the case, for example, of residues resulting from the pruning of fruit orchards, such as vineyards [15,16].

These woody biomasses have traditionally been valued through technologically more straightforward methods, such as combustion, but also through processes such as pyrolysis, with the production of biochar [16,17]. Although currently, both combustion and pyrolysis are processes standard in an industrial environment and considered advanced technology, their use dates back to ancient times [18]. Combustion is the oldest form of energy recovery that humanity has at its disposition, dating back to the times of Homo erectus, whereas the production of biochar, through an organized and intentionally carried out process, dates back at least to Ancient Egypt [19,20,21]. Thus, and because there is such a long history of the use and recovery of woody waste through these processes, they continue to be the most used for the disposal, recovery and management of woody waste [12].

The residues resulting from pruning operations in vineyards are a problem that presents some constraints for its resolution, mainly by the dispersion of materials, if this pruning operation is not planned correctly. For example, if since the early beginning of the operation, there is an aggregation of the materials that later facilitates the collection, or if the collection is carried out at the precise moment of the cut [22,23], when this logistical issue is overcome, the processes of valorization of vine pruning are diverse and have already been widely studied previously [24,25,26,27,28,29]. The potential to recover this type of waste is high, allowing great flexibility in its use, depending only on the intended final objective and the quantities available. The use of more complex processes, from a biorefinery perspective, to obtain products with higher added value allows, on the one hand, in a continuous and industrialized way, to process large amounts of waste, with production units located closer to the waste generating points. This way, it guarantees the supply of large quantities of raw materials, which can be stored and processed later [30,31,32]. On the other hand, this type of process also allows the final products have higher added value, justifying investments in the construction of these waste recovery units [33]. Examples of this could be biomass gasification units, charcoal production units, biomass power plants, or biomass pellets production units [24,34,35,36,37].

Regarding the Portuguese reality, which is also suitable for other countries in the Mediterranean region, such as Spain, Italy, or Greece, wherein parallel with large productions with very significative areas, capable of aggregating economies of scale that justify the investments necessary for these large and expensive technological solutions, there are myriad small vineyards, which mostly occupy only a few hectares, with wider territorial dispersion, and interspersed with other types of occupation and land uses [38]. This is the most recurrent situation in the Portuguese region that was selected for the present study, in which the owners of small vineyards are not able to find a solution for their waste [39,40]. In this way, as a solution for the large volume of waste generated, these are burnt on-site, without any use for the generated energy [41].

Small-scale recovery, such as the use of this waste as firewood, namely in traditional processes, was mainly as an option, e.g., its use in bakery ovens or traditional roasted piglet restaurants, which are so common in several regions of Portugal [34]. However, with the advent of electric and gas-fueled ovens, these practices are less frequent and cannot handle the increasing amounts of waste. These traditional practices can show which possibilities may serve as a solution if adequately adapted to the current reality [42]. The amount of vine pruning waste can be an alternative to other types of fuel, especially in locations closer to waste production areas, creating value chains while contributing to the resolution of problems associated with the disposal processes of these wastes [32,43,44,45].

In the specific case of woody residues of agricultural origin, such as vine pruning materials, the management process presents some constraints, namely related to the logistics associated with the collection process in the vineyards, the storage and subsequent transportation [46]. The usual practice of the pruning process, which also depends a little on the way the vineyard is organized, means that the pruners cut the branches and drop them to the ground, where they can later be collected and baled or pilled and shredded on-site, with the biomass chips being spread over the soil [34]. These difficulties are not very different from those encountered in the management of waste resulting from forestry operations because they present the same type of constraints, such as low density, low heating value, high moisture content, a significant content of inert contaminants, and large dispersion over the production area [47]. All these factors negatively contribute to the success of the waste management logistical process [23].

From the perspective of introducing sustainable practices and the circularization of the agrarian-based economy, efforts for the proper management of agricultural waste must be seen not from the perspective of a cost associated with the production process, but rather from the perspective of creating a value chain, which contributes to the success of the farm and the increase in business productivity [48]. Thus, the present research analyzes some forms of the recovery of residues from agricultural activity, specifically, the material resulting from vine pruning, through small-scale combustion processes, to create an innovative approach based on the creation of value chains of local or regional scale.

2. Materials and Methods

2.1. Location and Characterization of the Area under Study

For the collection of samples to proceed with the characterization of the materials, an area dedicated to the production of vines was selected, located in the parish of Refóios do Lima, in the municipality of Ponte de Lima (northern Portugal). In the “Vinhos Verdes” demarcated wine region, in the “Lima” sub-region. In the selected area, the entire vineyard used for the present study is composed of the local “Loureiro” variety, which is perfectly adapted to the soil and climate conditions of the territory in question. Figure 1 shows the location of the area under study and an image of the vineyard where the samples were collected.

It is a region with a temperate Mediterranean-type climate with a strong Atlantic influence, where the summer is mild and dry, and the sky is usually not very cloudy [49]. On the other hand, the winter is cooler, with high precipitation, and usually cloudy. Throughout the year, in general, the temperature varies from 7 °C to 26 °C (average temperatures) and is rarely below 2 °C or above 35 °C. Figure 2 shows the average distribution of temperature and precipitation throughout the year for the Ponte de Lima region.

2.2. Sampling and Material Preparation

In the area under study, vine pruning is usually carried out during January, always after all the vine leaves have fallen. This time, after the pruning was carried out in January 2022, samples of these same prunings were collected to quantify the biomass production capacity of the vineyard and collect samples for the laboratory characterization of the materials from a perspective of energy recovery. Ten sampling points were selected for the collection of samples as representative of the entire area covered by the vineyard. Namely, they were collected among the different types of soil existing in the place and represented the different altitudes at which the vines are planted. The ten selected collection points constituted the plants between supports, usually three in number, so each selected point provided three samples. Figure 3 shows one of these sample collection units, consisting of the two mainstays supporting the vine with the three plants.

After pruning, residual materials were collected and weighed. After weighing, they were dried for one week. This drying took place by natural direct exposure to air. After seven days, the materials were weighed to assess the evolution of the moisture loss of the materials. Figure 4 shows the vine pruning bales during the natural drying process.

In the year prior to the procedure described, in January 2021, a smaller-scale collection of material was carried out to obtain samples for laboratory characterization. Thus, several samples of vine pruning were collected, which were cut using electric pruning shears in dimensions between 2 and 5 cm, as shown in Figure 5.

2.3. Laboratorial Characterization

The objective was to analyze the properties of materials from a perspective of energy recovery; therefore, the laboratory characterization of the collected materials was carried out according to the sequence presented in the standard ENPlus ^®, enabling a direct comparison with other solid fuels derived from biomass, such as is the case of wood pellets produced from Pinus pinaster.

Table 1. Standards used in the laboratory characterization tests.

Standard	Description
ISO 17225-1: 2014	Solid biofuels—Fuel specifications and classes—Part 1: General requirements.
ISO 16948: 2015	Solid biofuels—Determination of total content of CHNO.
ISO 16967: 2015	Solid biofuels—Determination of major elements—Al, Ca, Fe, Mg, P, K, Si, Na and Ti.
ISO 16968: 2015	Solid biofuels—Determination of minor elements—Ar, Cd, Co, Cr, Cu, Hg, Mn, Mo, Ni, Pb, Sb, V and Zn.
ISO 16994: 2016	Solid biofuels—Determination of total content of S and Cl.
ISO 18125: 2017	Solid biofuels—Determination of calorific value.
ISO 21404: 2020 (en)	Solid biofuels—Determination of ash melting behavior.

presents the list of standards referred to in the standard ENPlus ^® and where the laboratory procedures used are described.

Elemental analysis (CHNO) was performed in LECO CHN628 apparatus, in which the operating principle consists of weighing a sample in a tin foil that is later placed in the autoloader and then introduced into the furnace containing pure oxygen, with carbon, hydrogen, and nitrogen being completely oxidized and the CHN contents calculated. Oxygen content on a dry basis is calculated by difference. Thermogravimetric analysis (TGA) was performed using ELTRA THERMOSTEP equipment. One gram of each sample was introduced into crucibles and placed inside an oven, along with an empty reference crucible. As the temperature increased, crucibles were weighed on a precision scale. Moisture, volatile, and fixed carbon contents were determined throughout the heating process. Lastly, the final residue represented the ash content. A TITROLINE 7000 titrator from SI Analytics was used to determine the chlorine content. For this procedure, sample preparation involves previous digestion of the sample, performed in a SINEO MDS-6G microwave since titration requires a liquid sample. Chlorine content determination is achieved by potentiometric titration. The lower and higher heating values were determined using an adiabatic bomb calorimeter, model 6400 Automatic Isoperibol Calorimeter, by PARR INSTRUMENT. After each procedure, the equipment provides the corrected temperature increase that is later used to determine the heating value. The determination of ash fusibility consists of monitoring the behavior of ash melting along a temperature ramp. The samples, converted to ashes, were subsequently placed in a plastic dish, where two drops of ethyl alcohol were added and homogenized. Then, this paste was transferred to a mold, where a cylinder is compacted. Subsequently, the cylinders were placed on a zirconia lamella and then placed inside the chamber of the ash fusibility furnace, which in this specific case was a SYLAB IF 2000 g device. Inductively coupled plasma optical emission spectrometry (ICP-OES) was used to determine trace elements and sulphur. The equipment used was a THERMO SCIENTIFIC (iCAP 6000 series). A peristaltic pump delivered the digested samples to an analytical nebulizer and introduced them into the plasma flame that broke down the samples into charged ions, releasing radiation with specific wavelengths.

2.4. Further Analysis

In addition to the materials collected for the laboratory characterization tests, more samples were also collected and prepared, as shown in Figure 5, to carry out combustion tests. This way, to conduct these combustion tests, 30 kg was collected in 2022, which also served to analyze the available diameters present in the materials to complement the comparative study with wood pellets. Thus, an amount of material was separated, totalizing 183 fragments, whose diameters were measured.

3. Results and Discussion

3.1. Characterization of Vine Pruning Samples

3.1.1. Laboratorial Results

The results obtained in the laboratory characterization are presented in the following tables.

Table 2. Elemental analysis (CHNO).

	C (%)	H (%)	N (%)	O (%)	S (%)	Cl (%)
Sample 1	46.48	6.36	0.710	45.79	0.0181	0.0001
Sample 2	45.23	6.42	0.616	46.47	0.0184	0.0007
Sample 3	47.12	6.05	0.280	48.42	0.0190	0.0008
Average	46.27	6.28	0.54	46.89	0.0185	0.0005
Standard deviation	0.95	0.20	0.23	1.37	0.0005	0.0003

presents the results of the elemental analysis, with the determination of the percentual contents of carbon (C), hydrogen (H), nitrogen (N), oxygen (O), sulphur (S) and chlorine (Cl).

Table 3. Thermogravimetric analysis (TGA).

	Moisture (%)	Volatiles (%)	Ashes (%)	Fixed Carbon (%)
Sample 1	3.74	77.83	1.42	19.51
Sample 2	3.77	77.84	1.41	19.46
Sample 3	3.51	77.72	1.42	19.78
Average	3.67	77.80	1.42	19.58
Standard deviation	0.14	0.07	0.01	0.17

presents the results of the thermogravimetric analysis (TGA), with the determination of percentual moisture content (%), volatile content (%), ash content (%) and fixed carbon (%).

Table 4. Determination of lower (LHV) and higher (HHV) heating value.

	HHV (MJ·kg−1)	LHV (MJ·kg−1)
Sample 1	18.41	17.42
Sample 2	18.01	17.07
Sample 3	18.95	17.78
Average	18.95	17.58
Standard deviation	0.006	0.000

presents the heating values (low and high) by calorimetry.

Table 5. Fusibility of the ashes. IDT—initial deformation temperature (°C); ST—softening temperature (°C); HT—hemispherical temperature (°C); FT—fluid temperature (°C).

	IDT (°C)	ST (°C)	HT (°C)	FT (°C)
Sample 1	888	1476	1572	1581
Sample 2	858	1570	1579	1588
Sample 3	901	1534	1578	1583
Average	882	1527	1576	1584
Standard deviation	22	47	4	4

presents the results obtained in determining the fusibility temperatures of the ashes.

Table 6. Analysis of the contents of major elements by ICP-OES.

	Al (mg·kg−1)	Ca (mg·kg−1)	Fe (mg·kg−1)	Mg (mg·kg−1)	P (mg·kg−1)	K (mg·kg−1)	Si (mg·kg−1)	Na (mg·kg−1)	Ti (mg·kg−1)
Sample 1	74.54	6972.46	31.15	1303.74	1101.95	8120.49	188.82	407.25	2.71
Sample 2	53.66	7722.37	38.57	1386.39	1077.50	8444.39	137.45	413.72	3.48
Sample 3	53.44	7641.21	32.29	1387.78	1107.98	8168.23	131.67	444.39	2.83
Average	60.55	7445.35	34.00	1359.30	1095.81	8244.37	152.65	421.79	3.01
Standard deviation	12.12	411.54	4.00	48.12	16.14	174.86	31.46	19.84	0.41

shows the content (mg·kg⁻¹) of the major elements, and

Table 7. Analysis of minor elements content by ICP-OES.

	As (mg·kg−1)	Cd (mg·kg−1)	Co (mg·kg−1)	Cr (mg·kg−1)	Cu (mg·kg−1)	Mn (mg·kg−1)	Ni (mg·kg−1)	Pb (mg·kg−1)	Zn (mg·kg−1)
Sample 1	0.58	0.58	0.40	0.48	23.16	39.64	0.63	0.29	14.51
Sample 2	0.88	0.34	0.20	0.34	26.48	43.44	0.41	0.10	14.53
Sample 3	0.73	0.39	0.32	0.04	25.15	40.95	0.13	0.09	18.40
Average	0.73	0.44	0.31	0.29	24.93	41.34	0.39	0.16	15.53
Standard deviation	0.15	0.13	0.10	0.22	1.67	1.93	0.25	0.11	2.02

shows the content (mg·kg⁻¹) of the minor elements.

The elemental analysis shows that the carbon content presented an average value of 46.27 ± 0.95%, the hydrogen content presented an average value of 6.28 ± 0.20%, the nitrogen content presented an average value of 0.54 ± 0.23%, and the oxygen content presented an average value of 46.89 ± 1.37%. From the determination of the sulfur and chlorine contents, it was found that the mean values were 0.0185 ± 0.0005% and 0.0005 ± 0.0003%, respectively.

The thermogravimetric analysis showed that the average moisture content was 3.67 ± 0.14%, the volatile content presented an average value of 77.80 ± 0.07%, the ash content presented an average value of 1.42 ± 0.01%, and the fixed carbon showed a content of 19.58 ± 0.17%. The moisture content obtained during the laboratory characterization was significantly low because the samples were subjected to a forced drying process in a laboratory oven during the sample preparation process for the remaining laboratory tests. This way, this moisture content should not be considered in the analysis of the thermal and combustibility properties of the materials under analysis.

The heating value determined for the vine pruning samples presented a value of 18.95 ± 0.006 MJ·kg⁻¹ for the higher heating value and 17.58 ± 0.000 MJ·kg⁻¹ for the lower heating value.

The analysis of the ash fusibility, produced by calcination of the vine pruning samples, showed an average IDT of 882 ± 22 °C, an average ST of 1527 ± 47 °C, an average HT of 1576 ± 4 °C and an FT of 1584 ± 4 °C.

The analysis of the major elements showed an average content of 60.55 ± 12.12 mg·kg⁻¹ for aluminum, an average content of 7445.35 ± 54 mg·kg⁻¹ for calcium, an average content of 34.00 ± 4.00 mg·kg⁻¹ for iron, an average content of 1359.30 ± 48.12 mg·kg⁻¹ for magnesium, an average content of 1095.81 ± 16.14 mg·kg⁻¹ for phosphorus, an average content of 8244.37 ± 174.86 mg·kg⁻¹ for potassium, an average content of 152.65 ± 31.46 mg·kg⁻¹ for silicon, an average content of 421.79 ± 19.84 mg·kg⁻¹ for sodium, and an average content of 3.01 ± 0.41 mg·kg⁻¹ for titanium.

The analysis of minor elements showed an average content of 0.73 ± 0.15 mg·kg⁻¹ for arsenic, an average content of 0.44 ± 0.13 mg·kg⁻¹ for cadmium, an average content of 0.31 ± 0.10 mg·kg⁻¹ for cobalt, an average content of 0.29 ± 0.22 mg·kg⁻¹ for chromium, an average content of 24.93 ± 1.67 mg·kg⁻¹ for copper, an average content of 41.34 ± 1.93 mg·kg⁻¹ for manganese, an average content of 0.39 ± 0.25 mg·kg⁻¹ for nickel, an average content of 0.16 ± 0.11 mg·kg⁻¹ for lead, and an average content of 15.53 ± 2.02 mg·kg⁻¹ for zinc. For mercury (Hg), the samples always presented a value lower than the minimum detection limit of the equipment used in the analysis.

3.1.2. Statistical Analysis of the Laboratorial Results

Using the Friedman one-way repeated measure analysis of variance by ranks, significant differences between the different parameters of the chemical analysis performed on the vine pruning were checked. For the results obtained for the elemental analysis, the mean values for the contents of C, H, N and O were 3.67, 2.00, 1.00 and 3.33, respectively. The Friedman test returned a p < 0.05; thus, the null hypothesis was rejected, i.e., there were differences between the mean ranks. This result indicates that, because the oxygen content is calculated from the sum of C, H and N, this content is directly dependent on the result of the other elements. The difference between the mean ranks for hydrogen and nitrogen contents tends to be low, as confirmed by Kendall’s concordance coefficient (0.042), i.e., p < 0.05 confirms the rejection of the null hypothesis and supports the difference between the mean ranks of the parameters for the two pairs of elements, C-O and N-H, respectively. When the elemental analysis was performed together with the results of sulfur and chlorine contents, there was a change in the mean ranks of the parameters, which became 5.67, 4.00, 3.00, 5.33, 2.00 and 1.00 for C, H, N, O, S and Cl, respectively. However, in this case, the Friedman test presented p < 0.05, confirming differences between the mean ranks, as also confirmed by the Kendall’s concordance coefficient, which also presented p < 0.05, which justified the rejection of the null hypothesis.

The thermogravimetric analysis also showed a similar trend to that observed for elemental analysis. The mean ranks for moisture, volatiles, ashes and fixed carbon were 2.00, 4.00, 1.00 and 3.00, respectively, with the Friedman test showing p < 0.05, indicating the differences between the mean ranks of these parameters, confirmed by the coefficient of agreement of Kendall, also with p < 0.05, and that rejected the null hypothesis.

The major elements Al, Ca, Fe, Mg, P, K, Si, Na and Ti presented mean ranks of 3.00, 8.00, 2.00, 7.00, 6.00, 5.00, 4.00, 5.00 and 1.00, respectively, also with the Friedman test showing p < 0.05, as well as p < 0.05 for Kendall’s concordance coefficient, once again rejecting the null hypothesis and confirming the differences between the mean ranks of this set of parameters. On the other hand, the minor elements As, Cd, Co, Cr, Cu, Mn, Ni, Pb and Zn presented mean ranks of 5.50, 4.33, 2.65, 2.50, 8.00, 9.00, 4.67, 1.33 and 7.00, respectively, with the Friedman test showing p < 0.05. This situation indicated that this set of parameters had equal mean ranks, confirmed by Kendall’s concordance coefficient, which also had p < 0.05.

Concerning the analysis of the chemical properties of vine pruning, it can be seen from the results obtained that there is no direct relationship between the different parameters. In other words, the variation in the content of a given element is not dependent on the variation in any other element, except for the oxygen content, determined by the differences between the carbon, nitrogen, and hydrogen contents, which can also include the sulfur and chlorine contents. On the other hand, when the carbon content was related to the LHV with the Pearson test, a positive correlation between the two parameters was verified (0.963) with p = 0.174, i.e., p > 0.05, which led to the acceptance of the null hypothesis, confirming the correlation between the two parameters. This condition justifies the high calorific value presented by the vine pruning, which, as has been seen, is directly related to the high carbon content.

3.1.3. Fuel Comparative Analysis

The results obtained for the characterization of the collected samples demonstrate that the quality of this residual biomass fits as a fuel that can be used in energy recovery processes. In fact, this finding has already been confirmed by several previous studies [16,50,51,52].

Table 8. Comparison of the parameters obtained for vine pruning with the limits imposed by the ENPlus ^® standard and with the values normally presented by wood pellets produced with Pinus pinaster (adapted from [24]).

Parameters	Units	A1	A2	B	Wood Pellets	Vine Pruning
Moisture	%	≤10	≤10	≤10	6.42	3.67 *
Ashes	%	≤0.7	≤1.2	≤2	0.62	1.42
LHV	MJ·kg−1	≥16.50	≥16.50	≥16.50	17.87	17.58
N	%	≤0.3	≤0.5	≤1.0	0.08	0.536
S	%	≤0.04	≤0.05	≤0.05	0.0045	0.0185
Cl	%	≤0.02	≤0.02	≤0.03	0.02	0.0005
ST	°C	≥1200	≥1100	≥1100	1215	1570
As	mg·kg−1	≤1	≤1	≤1	0.94	0.73
Cd	mg·kg−1	≤0.5	≤0.5	≤0.5	0.34	0.44
Cr	mg·kg−1	≤10	≤10	≤10	1.99	0.29
Cu	mg·kg−1	≤10	≤10	≤10	3.55	24.93
Pb	mg·kg−1	≤10	≤10	≤10	0.71	0.16
Hg	mg·kg−1	≤0.1	≤0.1	≤0.1	≤0.01	≤0.01
Ni	mg·kg−1	≤10	≤10	≤10	1.08	0.39
Zn	mg·kg−1	≤100	≤100	≤100	8.08	15.53

* The result of 3.67%moisture for the vine pruning corresponds to the value obtained by TGA. However, the real moisture value of the material at the moment of its use as firewood was in the range 15–25%, which corresponds to an LHV in the range of 14–16 MJ/kg.

shows a comparison between the results obtained for the vine pruning with the values obtained for a characterization presented by Nunes et al. for wood pellets certified to the ENPlus ^® standard [24].

The results obtained are mainly within the limits established by the standard ENPlus ^® and are very similar to those usually found in wood pellets produced with Pinus pinaster. Exception was made for the ash content, which with a value of 1.42% exceeded the limits imposed for categories A1 and A2, and could only be used to produce wood pellets to fit in category B. The same happened for the nitrogen content, which, with 0.536%, only enables its use in the production of category B wood pellets. On the other hand, in the case of copper, the value significantly exceeded the established limit by almost 2.5 times; therefore, it cannot be used exclusively as the only raw material to produce wood pellets subject to certification. This high level of copper may, however, have an explanation that is not related to the intrinsic properties of the biomass itself, but should instead be related to the use of Bordeaux mixture as a fungicidal treatment, which is commonly applied to vineyards in the region in two treatments, the first being applied in the last week of July, and the second during the third week of August. This situation can be extrapolated to calcium, which, although not part of the ENPlus ^® list, also exhibited a high value, even compared with the remaining major elements, with an average value of 7445.35 ± 44.54 mg·kg⁻¹. This situation should also be related to the application of a treatment, this time based on quicklime and sulphate, which are used to combat powdery mildew. This high content of calcium may act as a fondant for the ashes.

Although these parameters exceed the limits imposed by the ENPlus ^® standard and make it impossible to produce wood pellets exclusively with vine pruning, their incorporation into mixtures seems to be possible. In the case of mixtures incorporating 50% of vine pruning, the authors indicate that copper levels continue to be an impediment to the use of these materials in the production of certified wood pellets. When the mixture only incorporated 25% of vine pruning, the authors indicate that only the ash content remains above the limits imposed by the standard ENPlus ^® for products certified in category A1, but allows the production of wood pellets of category A2. With mixtures incorporating 10% of vine pruning, wood pellets can be certified in category A1. In this way, the possibility of incorporating these residual biomasses can be seen as an excellent possibility for the recovery of large amounts of waste, while using already established value chains, which can even have a double role from point to point from an environmental point of view and the management of forest resources, because they would allow significant savings in virgin raw materials.

3.2. Combustibility and Energy Recovery

As the laboratory characterization tests indicated, the thermal properties and the combustibility of the vine pruning are comparable with other commonly used fuels. They can be presented as a suitable product, both from the perspective of being used as raw material for incorporation in the production of wood pellets, combined with other biomasses, and to be used as a single fuel in applications such as firewood. As seen in Figure 5, the material cutting can be adjusted so that the final product is longer or smaller and looks similar to that of wood pellets. However, if the length is not an issue because it can be adjusted, the diameter can vary greatly.

From the granulometric analysis performed, it appears that the values obtained vary between a minimum of 2.65 mm and a maximum of 19.67 mm, with an average value of 7.78 ± 3.10 mm, with a variance of 9.67 mm. Compared with wood pellets that have a fixed value diameter, which can be 6 mm for pellets commonly used in domestic applications, and 8 mm, more frequently used in industrial applications, and with length to be limited by the standard ENPlus ^® at a minimum value of 3.15 mm and a maximum value of 35.0 mm, seems to present significant differences in dimensions. This difference in dimensions should not be a problem for industrial-type applications, which use high-throughput equipment, where the fuel feed augers are capable of processing both wood pellets and woodchips, thus having greater agility to process materials of different dimensions. On the other hand, domestic equipment, such as boilers and stoves, normally do not have this capacity, so the use of fuels in this equipment that does not present a certain homogeneity normally leads to clogging of the supply systems, damaging the equipment, and causing frequent cleaning interventions.

The use of vine pruning cut in dimensions between 20 and 50 mm for direct use in domestic fireplaces, with or without the use of an adapter, depending on the size of the openings of the bottom grate fireplace, can be a very viable alternative for domestic applications with several advantages. Figure 6 shows some aspects of the tests carried out in a domestic fireplace using an adapter.

This use of vine pruning as firewood presents several advantages. It allows many people who currently consume firewood as heating fuel to replace the purchase of traditional firewood, preferably produced with the wood of species such as oaks or pines, avoiding the exploitation of forest resources. At the same time, because vine pruning biomass is expected to have a significantly lower cost for the consumer than traditional firewood, this replacement will imply a significant reduction in heating costs for the consumer, thus contributing to mitigating energy poverty. This subject has been widely discussed in Portugal, and mainly affects populations living in rural environments, who are often older and without the financial capacity to bear the costs of heating their homes during the coldest and wettest period of the year. Finally, regarding the advantages of using vine pruning such as firewood, the question of storage in the domestic space arises; because they can be bagged, similar to what happens with wood pellets, it allows a more accessible accommodation of the fuel in basements or domestic storage rooms, taking up less space. Additionally, because the material can be bagged, it allows the consumer to purchase it in a way that is more in line with their needs, avoiding bulk purchase, which often exceeds the absolute need for the consumption of the year, leaving leftovers for the following year, with the corresponding equity tie for such a long period.

Despite all these advantages that are easily understood, perhaps the most significant advantage of all is the possibility of creating value chains at a local level or regional proximity, in which vineyards managers may place a new product on the market through the direct sale of vine pruning, creating a new value chain. This business model, in which producers sell the bagged fuel directly to the final consumer, can earn farmers more income. At the same time, from an environmental perspective, they eliminate the waste produced without resorting to less appropriate practices, as is the burning of leftovers, where the energy produced is not used. This business model can be even more efficient if, for example, fuel producers create customer loyalty networks, in which, by yearly production estimations, fuels are reserved for a customer portfolio, which knows in advance that have its firewood needs covered at a specific price. This model may also include a system for exchanging packaging, giving preference to reusable bags with the return, such as sackcloth, thus avoiding plastic. Models that include home delivery can also be considered, with previously agreed dates and quantities. Figure 7 shows a flowchart with the proposed business model.

Although a fuel preparation stage is presented, which involves drying the collected material and the production of woodchips, the costs associated with this processing can be considered low and do not significantly impact production cost estimations. The drying process considered in this business model is carried out naturally, with the vine pruning bales being stored preferentially in a covered place to avoid exposure to rain, thus allowing the material to dry as much as possible [53]. Preferably, in an ideal scenario where the producer has available space, the material collected in January, at the time of pruning the vines, is only available for consumption at the beginning of the following autumn. In September or October of the same year, the humidity of the materials naturally reaches 15–25%. In the case of woodchip production, the process considered in this business model was the use of small-scale shredding equipment, such as a woodchipper adaptable onto a tractor, usually with a shaft with a slipping clutch, or an organic waste electric shredder, which are types of equipment usually already available in agricultural facilities. This operation, as mentioned above, must be carried out when the sales period begins to avoid long periods of storage of the shredded material to avoid the risk of fermentation and its perishability.

In this way, a value chain is created in which the following aspects stand out:

• There is a prospect of valuing waste resulting from agricultural production—in this case, wine production—where the disposal of waste is carried out in line with the reduction in the carbon footprint, associated, for example, with the burning of leftovers, through the reduction in greenhouse gas emissions without using the energy;
• There is value creation resulting from the commercialization of waste, now transformed into fuel;
• There is a contribution to the preservation of forest resources as a result of the substitution of firewood of forest origin for others of residual origin;
• There is an effective contribution to improvements in the economic and social conditions of rural populations as a result of the creation of a new direct value chain established between producers and final consumers, with obvious advantages for both;
• Finally, there is a compelling valuation of endogenous resources with the application of a circular bioeconomy model, intending to increase the sustainability of the agricultural sector and promote rural development.

3.3. Residual Biomass Production Capacity

The amount of biomass produced per hectare of vineyard depends on the soil and climate conditions where the vineyard is located, the variety of the vine, the compass and density of the plantation and its age [54]. The planting compass is characterized by the distance of the vines between the rows and the distance of the vines in the row, expressed by the distance between rows (m) × distance in the row (m), whose product corresponds approximately to the area occupied by each plant (m²). The planting density corresponds to the number of plants per hectare, which is calculated by dividing the area of one hectare, which corresponds to 10,000 m², by the area occupied by each of the plants, expressed in m². The most common vine planting densities may vary from 952 plants·ha⁻¹ to 2222 plants·ha⁻¹, in accordance with the different types of compasses normally used in the vineyards of the demarcated region of Vinhos Verdes (available at https://viticultura.vinhoverde.pt, accessed on 12 February 2022). In the area selected for the present study, the following results were obtained in weighing residual biomass production per plant, shown in

Table 9. Results obtained in weighing the biomass produced per plant, in which each sampling point corresponds to a set of three plants between supports (each one the sampling points, corresponding to the vines planted between the support systems, supplied three samples).

Samples		Weight on Cut (kg)	Weight after Drying 1 Week (kg)
Sample 1	(1)	2.2	2.0
	(2)	2.3	2.1
	(3)	4.3	4.0
Sample 2	(1)	2.5	2.2
	(2)	3.3	3.1
	(3)	2.5	2.4
Sample 3	(1)	2.5	2.2
	(2)	2.1	2.0
	(3)	3.9	3.6
Sample 4	(1)	1.4	1.3
	(2)	2.6	2.3
	(3)	2.9	2.6
Sample 5	(1)	2.0	1.8
	(2)	1.5	1.4
	(3)	2.4	2.2
Sample 6	(1)	3.0	2.6
	(2)	3.5	3.3
	(3)	3.5	3.0
Sample 7	(1)	2.2	2.0
	(2)	4.5	4.1
	(3)	1.9	1.8
Sample 8	(1)	2.5	2.2
	(2)	1.7	1.6
	(3)	1.8	1.7
Sample 9	(1)	4.3	4.0
	(2)	3.1	2.9
	(3)	2.3	2.1
Sample 10	(1)	4.4	4.2
	(2)	3.4	3.1
	(3)	4.6	4.4

.

From the results, at the time of cut, an average value of 2.83 ± 0.94 kg is obtained for each sample. However, after a drying period of seven days, this value decreases by 10%, with an average weight per plant of 2.61 ± 0.89 kg. The drying process tends to occur homogeneously, and the material has a high capacity for moisture loss after cutting, ranging from approximately 32% moisture to 20–25% after drying for one week. This result is in line with those usually found in firewood produced with other species such as oaks, acacias, or pines. Based on these results, using the values obtained after drying over a period of seven days, the values shown in

Table 10. Potential biomass production (kg·ha⁻¹) and estimated revenues ((EUR·ha⁻¹) for the most common vine planting densities.

	Vine Planting Densities (Plants·ha−1)
	952	1111	1333	1666	2222
Potential biomass production (kg t·year−1·ha−1)	2485 ± 847	2900 ± 989	3479 ± 1186	4348 ± 1483	5799 ± 1978
Estimated revenues (EUR·ha−1)	224 ± 76	261 ± 89	313 ± 107	391 ± 134	522 ± 178

were obtained, calculated from the combination of the vine planting densities and the average values of biomass produced per plant after drying.

Bearing in mind the available amounts on average, calculated for vineyards planted with the “Loureiro” variety, in the Ponte de Lima region, it appears that it is possible to produce significant amounts of residual biomass, which may vary between a maximum of 5799 ± 1978 kg·year⁻¹·ha⁻¹, for densities of 2222 plants·ha⁻¹, and a minimum of 2485 ± 847 kg·year⁻¹·ha⁻¹, for densities of 952 plants·ha⁻¹. The average yield for the region should be close to 3500 kg·ha⁻¹, corresponding to the density of 1333 plants·ha⁻¹, which can be considered as corresponding to the mode because it is the most frequently used in the region where the present study was carried out. However, there is a high variance directly related to the possible planting densities, which can range from 952 to 2222 plants·ha⁻¹. The results presented in Table 9 seem to follow a normal distribution, because the one-sample Kolmogorov–Smirnov test resulted in p > 0.05, so the null hypothesis was accepted. This framework may help to understand the fact that the median of the distribution is closer to 3500 kg·ha⁻¹, so the value resulting from the mode of vine planting density in the region where the study was carried out is accepted, and which corresponds to the value most commonly used in vine planting, as the most likely value for the quantification of the biomass produced. This analysis was based on a survey on Google Forms (https://forms.gle/erpGfC4tNYb9DrG36, accessible between 1 April 2022, and 12 April 2022) submitted by email to winemaking cooperatives in the region, with the request for distribution to its associates and contacts. A total of 92 answers were obtained, among which was the question “What is the planting density that you use in your vineyard?”, to which 41 participants answered “1333 plants·ha⁻¹”. In other words, about 45% of the winegrowers in the region point to this planting density as the most commonly used, highlighting it among the other possibilities. These estimated biomass yields enable calculations of the potential revenue, based on a price per ton of firewood of 90 EUR·t⁻¹, as presented in Table 10.

For the end user, the acquisition of this residual biomass at a price of 90 EUR·t⁻¹ presents itself as a significant benefit, because the market value of wood pellets varies between EUR 3.49 and EUR 3.99 for each 15 kg bag, which corresponds to an average price of EUR 3.74 per bag [55]. Thus, the cost per ton of these wood pellets is EUR 250, including VAT. This significant difference in prices is justified because preparing the biomass from vine pruning does not involve significant industrial processing, and the proposed bagging format is also the responsibility of the end-user, thus reducing the cost of bagging. On the other hand, the production of wood pellets is a complex industrial process which involves energy-intensive steps, such as, in addition to shredding, the use of refining mills and drying. Packaging can also be an additional factor of unnecessary costs considering this proximity business model.

Compared with other types of firewood, the price may not be the most attractive factor because the lowest market value was used as a reference for assigning a value to the material resulting from vine pruning, which varied, depending on the type of firewood and the place of delivery, between 90 EUR·t⁻¹ and 150 EUR·t⁻¹. The main advantage can be attributed to the fact that the consumer can purchase smaller quantities at each purchase, avoiding the availability of capital in a single time. However, mainly the occupation of space for storage, because the acquisition of firewood in the traditional method implies the purchase of a certain minimum quantity, as a way of including the transport and storage of firewood, which generally corresponds to 1 ton. Another factor that can be considered is the willingness to pay by the consumers, who may understand that in this way, they are actively reducing their ecological footprint by contributing to the creation of a circular bioeconomy system.

4. Conclusions

The residues resulting from the fruit tree pruning operations can be considered an environmental problem because, in most cases, its elimination is processed through the burning of the leftovers in the field. In this way, the valorization of vine pruning through energy recovery seems to be an exciting possibility, mainly if it is associated with creating small-scale value chains. In this study, it was demonstrated that vine pruning as firewood for domestic consumption could be viable. As verified by the obtained results, vine pruning as firewood for domestic applications is comparable to conventional firewood, both in terms of heating value and general quality, referring to other parameters. Additionally, from an economic point of view, vine pruning is competitive with other types of firewood and may even present more advantageous conditions. In addition to contributing to the elimination/management of waste generated in agricultural activity, this solution contributes to creating a local-scale business model, which creates value for farmers in a circular bioeconomy and sustainable rural development perspective.