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A B S T R A C T
The use of biogas as an alternative to using liquefied petroleum gas 
(LPG) for cooking food in the context of family farming is something 
recent and has ample room for growth. The aim of this study was to 
evaluate the use of the Sertanejo biodigester by farming families as a 
social technology for cooking gas production, as well as an alternative 
energy source. It also aimed to identify elements which contribute to 
disseminating this technology as an alternative to the use of firewood, 
charcoal and LPG. Quali-quantitative approaches were used following 
the exploratory method, with interviews and non-probabilistic 
sampling. A population with 132 units of biodigesters in the Agreste 
mesoregion of the State of Pernambuco was considered, with 
83 interviews being collected. The results indicated that the Sertanejo 
biodigester social technology provides an increase in the income of 
farming families, avoids the use of firewood and charcoal for cooking 
food and produces biofertilizer for crops. They also showed that its 
non-continuous use or deactivation is related to a lack of raw material 
and the need for maintenance. Given this scenario, its implementation 
must consider the availability of a raw material source in the production 
unit and the potential for biogas production from the existing herd and 
consumption demand. It is recommended to strengthen arguments 
of economic and environmental impact for low-income families to 
disseminate this technology; to encourage the use of biogas associated 
with other activities in the production system; and to incorporate 
biodigestor social technology in rural credit financing lines.

Keywords: Family farming; social technology; biogas; National Rural 
Housing Program; climate changes; semi-arid region.

R E S U M O
A utilização do biogás como alternativa ao uso do gás liquefeito de 
petróleo (GLP) para cocção de alimentos no âmbito da agricultura 
familiar é algo recente e com amplo espaço de crescimento. O objetivo 
deste estudo foi avaliar o uso do biodigestor sertanejo por agricultores 
familiares como tecnologia social para produção de gás de cozinha, como 
fonte alternativa de energia. Visou, também, identificar elementos que 
contribuam para a divulgação e a disseminação dessa tecnologia como 
alternativa ao uso de lenha, carvão vegetal e GLP. Utilizou-se abordagens 
quali-quantitativas, seguindo o método exploratório, com entrevistas e 
amostragem não-probabilística. Foi considerada uma população com 
132 unidades de biodigestores na mesorregião do Agreste Pernambucano, 
sendo coletadas 83 entrevistas. Os resultados indicaram que a tecnologia 
social do biodigestor sertanejo proporciona incremento na renda das 
famílias agricultoras, evita o uso de lenha e carvão vegetal para cocção de 
alimentos e produz biofertilizante para os cultivos. Também mostraram 
que o seu uso não contínuo ou desativação está relacionado à falta de 
matéria-prima e à necessidade de manutenção. Diante desse cenário, sua 
implantação deve considerar a disponibilidade de fonte de matéria prima 
na unidade de produção e o potencial de produção de biogás a partir do 
rebanho existente e da demanda de consumo. Recomenda-se fortalecer os 
argumentos de impacto econômico e ambiental para as famílias de baixa 
renda para a disseminação dessa tecnologia; estimular o uso do biogás 
associado às demais atividades do sistema de produção e incorporar a 
tecnologia social biodigestor nas linhas de financiamento de crédito rural.

Palavras-chave: agricultura familiar, tecnologia social; biogás; Programa 
Nacional de Habitação Rural; mudanças climáticas; semiárido.

Sertanejo biodigestor: a social technology, an alternative source of energy
Biodigestor sertanejo: uma tecnologia social, fonte alternativa de energia
Reginaldo Alves de Souza1  , Marília Regina Costa Castro Lyra1  , Renata Maria Caminha Mendes de Oliveira Carvalho1  , 
José Coelho de Araújo Filho1  

1Instituto Federal de Educação, Ciência e Tecnologia de Pernambuco – Recife (PE), Brazil.
Correspondence address: Reginaldo Alves de Souza – Rua Visconde de Mamanguape, 40 – Encruzilhada – CEP: 52030-010 – Recife (PE), Brazil. 
E-mail: alves.reginaldo@gmail.com
Conflicts of interest: the authors declare that there are no conflicts of interest.
Funding: Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq).
Received on: 11/23/2020. Accepted on: 08/05/2021.
https://doi.org/10.5327/Z21769478987

Revista Brasileira de Ciências Ambientais
Brazilian Journal of Environmental Sciences

Revista Brasileira de Ciências Ambientais
Brazilian Journal of Environmental Sciences

ISSN  2176-9478 
Volume 56, Number 1, March 2021

This is an open access article distributed under the terms of the Creative Commons license.

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mailto:alves.reginaldo@gmail.com
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Introduction
The causes and consequences of climate change demand efforts in 

different sectors and different players. One of these efforts concerns 
the search for alternatives to the current hegemonic energy matrix. 
Another refers to the adaptation to ongoing climate processes. In this 
universe of technological options, the biodigester is considered a social 
technology for the production of biogas (methane) to supply part of 
the energy needs of family farming as an alternative to the use of Liq-
uefied Petroleum Gas (LPG), firewood and charcoal.

According to Martins et al. (2010), the ability of family farmers to 
adapt to climate change cannot be reduced to the possibility of adopt-
ing some practices apparently adjusted to a certain abnormal climate 
phenomenon, but it has to be understood as a result of the learning 
capacity to deal with the new situation.

Discussions around biogas production are not limited to a technical 
debate about the fermentation process and the efficiency of biodigester 
models. It is also associated with the broader debate on environmental 
sustainability, the growing need for clean energy production, reduced 
use of natural resources and especially related to a reduction in green-
house gas (GHG) emissions. In the opinion of specialists regarding this 
theme, it is important to consider that global warming caused by the 
increase in the emission of greenhouse gases in the Earth’s atmosphere 
can cause changes to terrestrial ecosystems, modifying global vegeta-
tion patterns (Nobre et al., 2007, p. 7). Such threats were recently reaf-
firmed in the sixth Assessment Report of the Intergovernmental Panel 
on Climate Change, which reveals that the global surface temperature 
will continue to increase until at least the middle of the century in all 
considered emission scenarios (IPCC, 2021, p. 18).

Under this perspective, there is a growing need to move towards 
expanding the use of renewable, non-polluting or low-emission green-
house gas sources of energy to the detriment of non-renewable ener-
gy, the main GHG emitters. Data presented by the Energy Research 
Company (EPE) (Table 1) indicate that the participation of renewable 
sources in the national energy matrix in the period from 2008 to 2018 
did not change significantly, varying negatively when evaluating the 
share of renewable sources, which contributed 45.6% to the national 
energy matrix in 2008, and represent 45.3% in 2018 (EPE, 2019, p. 56).

However, it can be seen that there are changes to the shares in the 
scope of renewable sources, with a reduction of 1.5 percentage points 
(pp) in the use of hydraulic energy, 3.2 pp in the use of firewood and 
charcoal, and an increase in the share of other renewables of 2.5 pp; 
furthermore, the contribution of solar energy begins in 2018 with 0.1% 
of the national energy matrix. Despite the diversification of the nation-
al energy matrix, biogas is still not highlighted as a renewable source 
of large-scale energy potential, being considered by EPE as incipient 
(EPE, 2019, p. 55-56). 

Interest in this research was aroused by the potential that the bio-
digester has for producing cooking gas associated with a considerable 
number of farming families that can incorporate this technology into 

their production processes, and takes the project “Biodigesters, A So-
cial Technology in the National Rural Housing Program (PNHR)”, 
implemented by the NGO Diaconia in 2013, as a reference, with the 
purpose of disseminating the use of biodigesters through training, to 
produce and manage cooking gas (methane biogas).

One of the main references in the social technologies (ST) registry 
with a focus on rural development and sustainability is the Bank of 
Social Technologies (BTS) of Fundação Banco do Brasil (FBB), where 
the backcountry biodigester is described as a social technology that 
produces biogas from animal manure, and is used in stoves to prepare 
family food (FBB, 2018). 

Several authors point out that the emergence of ST is due to an ear-
lier process associated with appropriate technologies. Rodrigues and 
Barbieri (2008, p. 1071) describe the emergence of this movement in 
the 1960s and 1970s, according to which – and citing Kaplinski (1990 
apud Rodrigues and Barbieri, 2008, p. 1071) –, “it would be associated 
with a reaction to post-war economic growth patterns.” In addition to 
the term ST, the authors retrieved other terms related to the example 
of the term intermediate technology created by Schumacher (1979 
apud Rodrigues and Barbieri, 2008, p. 1071), according to the authors, 
indicating “a technology that combines elements of traditional tech-
nologies with those of advanced technologies.” The authors also refer 
to the terms alternative technology, defended by Dickson (1974 apud 
Rodrigues and Barbieri, 2008, p. 1071), and soft technology, proposed 
by Clarke (1976 apud Rodrigues and Barbieri, 2008, p. 1071). 

Table 1 – Share of different energy sources in the national energy matrix, 
from 2008 to 2018.

 Energy sources
Share (%)

2008 2018

Non-renewable 54.5 54.7

Oil and Derivatives 36.7 34.4

Natural gas 10.3 12.5

Mineral Coal and Coke 5.5 5.8

Uranium (U3O8) 1.5 1.4

Other non-renewables 0.5 0.6

Renewables 45.5 45.2

Biomass (derived from sugarcane) 17.0 17.4

Hydraulics 14.1 12.6

Firewood and charcoal 11.6 8.4

Other renewables 2.8 5.3

Wind - 1.4

Solar - 0.1

Source: adapted from EPE (2019).



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In this historical review of the emergence of ST, Dagnino et  al. 
(2004, p. 19) refer to the struggle of the Indian people against the Brit-
ish rule, where the reformers of that society had “the rehabilitation and 
development of traditional technologies practiced in their villages” as 
a fighting strategy, having as a great reference the spinning wheel ma-
chine popularized by Gandhi, recognized as the first technologically 
appropriate equipment. However, according to the authors, the concept 
of appropriate technology (AT) was introduced in the Western world as 
a result of the creation by Schumacher of the Appropriate Technology 
Development Group and the publication of the book Small in 1973 is 
beautiful: economics as if people mattered, translated into over 15 lan-
guages. For the authors, this movement towards appropriate technology 
lost momentum in the early 1980s as the neoliberal thought expanded.

Ventura et  al. (2012, p. 606) suggest the need to discuss incor-
porating social technologies to the new institutional framework of 
the Post-Kyoto climate regime as one of the instruments to combat 
climate change, in fact contributing to negotiate GHG emission re-
duction projects in the carbon market, as they not only promote the 
transfer of technologies, but also the development of technologies 
suited to each social and environmental reality of the host communi-
ties. According to the authors, applying technologies for coexistence 
with the semi-arid region, especially the biodigester, cisterns and de-
salination plant, has been characterized as a cultural perspective that 
guides development with the purpose of improving living conditions 
and promoting citizenship through socioeconomic and technological 
initiatives.

In addition, Jiménez and Zambrano (2018) conclude that social 
technologies present themselves as modern options and adapt to small 
and medium rural enterprises with a satisfactory cost-benefit ratio that 
enables the relief of structural problems, thereby allowing the direct 
participation of rural communities in the implementation process and 
effectively contributing to develop individual and collective awareness 
of sustainability in the semi-arid region of the country.

According to Gualdani and Burgos (2020), the concept of ST is 
quite broad and flexible thanks to its experimentation character and 
the scope of possibilities for framing different types of solutions to local 
problems, with ST being defined by several authors as techniques, pro-
cedures, processes and methodologies collectively developed in order 
to solve a problem so as to socially include those involved, ensuring 
quality of life and environmental gains. They also highlight the low 
cost usually related to the availability of local materials included in the 
assembly in this conceptual universe, as labor and time invested must 
also be considered as social capital employed in its development; repli-
cation and reapplication concepts when it comes to reproduction from 
a step-by-step basis and the reproduction of ST in broader parameters 
which enable its improvement, including methodological adaptation 
and incorporating other materials; and that the practices identified as 
ST consequently have a “step-by-step” process, a development method-
ology and not necessarily a protocol.

The proposed study was directed to a specific biodigestor model 
called “sertanejo biodigestor,” resulting from an adaptation proposed 
by the NGO Diaconia to the Indian model with technology used in 
plate cisterns widely spread across the semi-arid region (Mattos and 
Júnior, 2011, p. 7). 

The innovative aspects proposed by the NGO Diaconia to adapt 
the technology included the materials for constructing the equip-
ment. However, they must be analyzed from the point of view of con-
struction practicality, results in biogas production and total costs of 
the equipment. According to the NGO Diaconia (2016), there is a 
significant number of Sertanejo biodigesters deployed in the Agreste 
region of Pernambuco, and part of this equipment is totally or par-
tially deactivated. This fact leads to the need for identification of the 
weaknesses regarding the adaptation to the dynamics of farming 
families with the technological innovation that gave rise to one of the 
focuses for research.

In a complementary way, the high cost of LPG can compromise 
the family income, essentially of the farming families, in view of their 
non-fixed income associated with the productive processes when 
it is not linked to social security and complementary programs for 
income distribution. According to the data presented by the NGO 
Diaconia, a farming family spends 9.32% of the minimum wage on 
the purchase of LPG monthly, or collects 21.06 kg of wood to pre-
pare food. It is then a problem related to family income and that the 
biodigester can effectively contribute with biogas (methane) to the 
detriment of the use of LPG. However, the question is what is the 
actual contribution of the biodigester when it comes to increasing 
family income? In economic terms, it is necessary to check whether 
the biodigester is really capable of promoting economic gains, con-
sidering the references presented by the NGO Diaconia (s.d., p. 8), 
suggesting that the use of the biodigestor can provide families with 
savings in monthly expenses equivalent to one and a half canisters of 
LPG, equivalent to 10% of the minimum wage.

Therefore, the aim of this study was to evaluate the use of the Ser-
tanejo biodigester by farming families in the Agreste region of Pernam-
buco as a social technology for producing cooking gas, as an alternative 
source of energy and to mitigate climate change. It also aimed to iden-
tify economic and social elements that contribute to disseminating this 
technology as an alternative for cooking gas production to replace the 
use of firewood, charcoal and LPG for domestic activities in the context 
of family farming in the semi-arid region. 

The study starts from two basic hypotheses: the use of the biodi-
gester social technology provides an increase in the income of farm-
ing families due to a reduction in the use of LPG, avoids the use of 
firewood and charcoal and contributes to producing biofertilizer for 
the family’s crops; the continuous non-use or deactivation of the bio-
digester is related to a lack of raw material, requirements in equipment 
maintenance (which takes a lot of work) and/or the lack of labor to 
maintain the equipment.



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Material and methods

Study area
The study considered the municipalities of Bom Conselho, Caetés, 

Jupi and São Bento do Una, located in the Agreste mesoregion of Per-
nambuco as its geographic focus (Figure 1), taking the quantity of 
biodigesters deployed in that territory belonging to the participating 
families of the Biodigestor Project as a reference, as executed by the 
NGO Diaconia.

The Sertanejo Biodigestor (Figure 2) is described by Mattos and 
Júnior (2011) from the Sertanejo Biodigestor Manual, a component of 
the Sustainable Land Management Project in Sertão, a publication of 
the Dom Helder Câmara Project (PDHC). Another reference found for 
this type of biodigester is the NGO Diaconia’s booklet, 12 steps to build 
a biodigestor as a product of the “Biodigestors: A Social Technology in 
the National Rural Housing Program” project, with support from the 
Caixa Socioenvironmental Fund (FSC). As shown in the two manuals 
mentioned above, the Sertanejo biodigester adopts the same principles 
as the Indian model, meaning it is a structure formed by an inlet box 
(herein referred to as the cargo box), a storage tank (also called the bio-
digestor tank or main tank), a gas storage hood coupled with a structure 
to capture the gas produced and a waste outlet box (herein referred to 
as discharge box). It is observed that the main difference between this 
model and the others is the type of material used for its construction as a 
way of adapting to small rural properties. While the Indian and Chinese 
models use masonry to build the fermentation tanks, in this model the 
construction is made with cement plates using the same construction 
principle as the Precast Plate Cisterns in cylindrical shape, according to 
Figure 3. The cistern is cylindrical in shape, covered and semi-buried. 
Its operation provides for the capture of rainwater using the roof of the 
house, which drains the water through gutters (ASA, 2021).

The waste input and output boxes do not differ in the type of ma-
terial used, only in the format. On the other hand, for the hood or gas-
ometer, which is made of metal in the Indian model and with masonry 
in the Chinese model, the decision was to adopt a PVC box normally 

used for water storage in an inverted way in the Sertanejo model, which 
receives a zinc and earth structure on top to act as a counterweight. The 
way the gas is captured is another great differential, as a 20-liter bottle 
adapted to receive and distribute the gas is used. 

Figure 1 – Geopolitical division map of Pernambuco.

Figure 2 – Sertanejo biodigester with maximum biogas load. Angico Site, 
Bom Conselho-PE, by Wanderley Nunes and Cláudio Almeida, 2020.

Figure 3 – Parts of the Sertanejo Biodigestor.



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By presenting the results of the work developed by the Network 
of Biodigesters for Latin America and the Caribbean (RedeBioLAC) 
to identify barriers and mechanisms to overcome them, aiming at the 
massification and democratization of medium and small scale bio-
digesters in Latin America and the Caribbean (LAC), Herrero et  al. 
(2016) emphasize the need to adapt the technology to the user (and not 
the other way around), and that the visibility and dissemination of bio-
digesters must fully consider their environmental aspects of changing 
the production and energy matrix and self-sufficiency for the producer.

According to the Diaconia NGO (s.d.), the “Sertanejo Biodigestor” 
has the following benefits, as shown in Chart 1. 

It is important to consider that biofertilizers are a by-product of 
the effluents from the biodigester, the digestate, which, according to 
Nicoloso et al. (2019, p. 122), should follow the fundamental principles 
of fertilizer management and soil fertility already established and con-
stantly refined by research.

The nature of this study
According to the definitions adopted by Gerhardt and Silveira 

(2009, p. 31), this study is classified as exploratory regarding its ob-
jectives, as it is the method which aims to provide greater familiarity 
with the problem with a view to making it more explicit or build hy-
potheses. It is configured as qualitative and quantitative in its approach, 
and documentary and field data were used based on interviews and 
questionnaires as the data source. Non-probabilistic sampling was also 
used, defended by Guimarães (2008) as a convenience sample formed 
by elements that the researchers gathered because they had them, or 
the researchers makes use of data which are more within their reach, 
which in this case is access to families with biodigesters. 

Sample
The population targeted by this study is part of the universe of farm-

ing families residing in houses financed by the PNHR of Caixa Econômi-
ca Federal (CAIXA), benefiting from the implementation of 395 biodi-
gester units in 39  municipalities of 06 states of the Federation: Bahia, 
Goiás, Minas Gerais, Pernambuco, Rio Grande do Sul and Santa Cata-
rina. A total of 24 families in Bahia were benefited; 61 in Minas Gerais; 
50 in Goiás; 52 in Santa Catarina; 67 in Rio Grande do Sul; and 141 in 
Pernambuco. The project concentrated its actions in the municipalities 
of Bom Conselho, Caetés, Jupi and São Bento do Una, in the state of Per-
nambuco, all belonging to the Agreste mesoregion of Pernambuco, with 
the goal of implementing 132 units (Diaconia, 2016, p. 8). 

From a sampling point of view, a sample based on these data was es-
timated, which met the expectation of verifying the abandonment rate of 
using the biodigesters and measuring their impact on family dynamics. 
Therefore, the finite population of 132 family units of biodigesters imple-
mented in the Agreste mesoregion of Pernambuco was considered, and 
the probability of continuous non-use or deactivation of the biodigesters 
was estimated in 15%, with a 95% confidence level, adopting the associ-
ated variable of 1.96 and a standard sampling error of 5%. Thus, applying 
the Equation 1 for sample definition suggested by Meunier et al. (2001), 
we would need to apply 75 interviews (57% of the total population), and 
83 samples were collected during the field visit process, reaching a repre-
sentation of 63% of the families using the biodigester. 

 (1)

Where:
n = calculated sample (size);
N = population (families with biodigesters) (132);
Z = standardized normal variable associated with confidence level - 
95% (1.96);
p = probability of biodigester deactivation (%) (0.15%);
e = sampling error (5% standard) (0.05%)

Data used in the study
Semi-structured interviews, systematic observations and photo-

graphic records were used as the primary data collection techniques 
carried out from the field survey. The semi-structured interview was 
the main instrument to respond to the general objective, as well as to 
seek subsidies which would allow confirming or denying the present-
ed hypotheses. Thus, data collection took place in the municipalities 
of Caetés, Jupi and São Bento do Una, maintaining distinct audienc-
es, defined by: families participating in the biodigestor project in the 
Agreste region of Pernambuco; community leaders; families with con-
solidated use of the Sertanejo biodigester in the Sertão do Pajeú region, 

Chart 1 – Benefits pointed out by the NGO Diaconia with the use of the 
Sertanejo Biodigestor.

Where Benefits

In the 
environment

- Firewood is not taken from the forest for cooking
- Contributes to reducing deforestation and the effects 

of climate change
- Prevents methane gas released by the natural 

combustion of animal manure from being released 
into the atmosphere

On health

- The biogas produced when used in the stove does 
not release smoke, preventing respiratory problems

- It contributes to the health of animals by collecting 
waste and cleaning corrals and pigsties, reducing 
infestation by worms and flies

On the Family 
income

- Saves a bottle and a half of LPG gas per month
- Produces organic fertilizer and biofertilizers

In Agriculture
- Produces natural fertilizers: biofertilizer and tanned 

manure, which can increase soil fertility and improve 
production

Source: Diaconia (s.d.).



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and the NGO Diaconia’s technical team members. Descriptive statistics 
according to Guimarães (2008) were used to treat the collected data.

Results and Discussion
This topic is dedicated to systematizing and interpreting the data 

generated in the study. The analysis addresses aspects related to the use 
of technology, economic and environmental impacts, and the role of 
social organizations in the process of mobilizing families.

Quadros (2009) defends the use of the biodigester in family farm-
ing in the Semi-arid region as a means of overcoming energy shortages 
resulting from economic and environmental impacts as a consequence 
of the use of firewood and cooking gas. In this perspective, he sug-
gests the biodigester as an alternative to use goat and sheep manure for 
energy generation (biogas) and fertilizer (biofertilizer), and concludes 
(among other issues) that it has a high potential for replication in fam-
ily farming as it has a high cost/benefit ratio with the generation of 
biogas and organic fertilizer. The data that we will see below corrobo-
rates this statement, as they present important subsidies for the debate 
on using the biodigester in family farming, especially in the semi-arid 
region, related to the acceptance of the technology, dimensioning bio-
gas production at the expense of the available raw material, in addition 
to bringing elements related to environmental, economic and social 
aspects with the use of biodigesters in the family agroecosystem.

It is important to understand that the following data refer to a study 
dimensioned by three associated variables: family farming, semi-arid 
and Sertanejo biodigester as a proposal for a technology to produce 
cooking gas in the context of family farming, therefore constituting a 
very peculiar context. In any case, based on the work developed by 
Herrero et al. (2016) with the purpose of giving visibility to the positive 
impacts of the use of the biodigester in sustainable family, community 
and productive development, it was possible to identify several expe-
riences in Latin America which corroborate the results presented in 
this work. In addition, those conducted in the state of Ceará, by Barros 
et al. (2020) make reference to the work of the NGO Cetra, which built 
around 300 biodigesters in 20  municipalities in Ceará between 2015 
and the first quarter of 2020.

It should be noted that Non-Governmental Organizations (NGOs) 
play a leading role in the work of multiplying the use of biodigesters 
for producing biogas in the context of family farming, such as the work 
developed by Diaconia and Cetra, who, together, are responsible for 
implementing more than 600 Sertanejo biodigesters, mainly in the 
semi-arid region of the Northeast.

Implementation and use of the biodigester
The data collected indicate that a considerable part of the families 

(around 25%) was unable to specify the date that the biodigester was 
installed on the property. However, it was possible to register that the 
first units implemented in the surveyed municipalities (about 2%) date 
from the end of 2014. The vast majority (around 71%) was implement-

ed between the period from January 2015 to October 2016; this means 
a majority of families had three to four years of experience with the 
use of this technology, considering the end of 2019 as a reference. One 
third of the families (32.5%) had their biodigesters deactivated (at the 
end of 2019) and another group (about 22% of the sample) was not us-
ing the produced biogas. Therefore, these numbers can be considered 
quite expressive, especially when the economic and environmental ap-
peal associated with the biodigester technology is highlighted.

According to Herrero et al. (2016), the work developed by the NGO 
PROSUCO in Bolivia, with the implementation of 40 biodigesters in 
10  municipalities, enabled approximately 50% to be consolidated as a 
reference in the supply of bio-inputs and in research and innovation. 
According to Jiménez and Zambrano (2018), the Technological Insti-
tute of Costa Rica installed 38 biodigester units in 4 rural communities 
in the city of Limón in Costa Rica, intended for the treatment of organic 
waste, mainly from swine, and used only as an energy source for food 
preparation, where 28 remain active, while 10 units (26%) are disabled 
due to lack of interest from families or due to system breakdowns. 

Aspects related to the advantages and disadvantages of using the 
biodigester from the perspective of families who deal directly with the 
technology are diverse, but point to a certain consensus. The data sys-
tematized in Table 2 clearly shows how the economic issue stands out 
as an advantage for the use of the biodigester, being pointed out by 94% 
of the families as something important, followed by practicality (43%) 
and abundant production of biogas (12%). This is also the opinion of 
the reference families of Sertão do Pajeú, where the majority (80% of 
the sample) claim to have decided to implement the biodigester due 
to aspects related to reducing expenses with the purchase of LPG gas 
associated with its high cost. 

About 90% of the sample referred to savings or improvement in 
family income when asked about the advantages of using the equip-
ment. The interviews carried out with community leaders in the mu-
nicipalities also follow the same opinion. The economic factor stands 
out as the main advantage for most respondents, in addition to report-
ing the fact that it is easy to handle and performs well in cooking food.

The opinion of the families in the Pajeú Region does not differ from 
the narrative presented above, as 90% of them refer to issues related to 
the economy when justifying that they are no longer able to purchase 
gas. It was also the reason why 80% of them decided to implement it 
considering the difficulties of finding firewood, aiming to replace the 
use of firewood and charcoal, and also considering the fact that it is a 
clean, non-polluting gas as an advantage.

A work developed by Silva and Correia (2020) in Oeste Potiguar 
considering a universe of 21 families refers to the degree of accept-
ability of the Sertanejo biodigester technology used for more than two 
years, with 42% of them in use for more than five years, and indicating 
that 100% of the families rated the technology as great or good.

Families point out issues related to work regarding equipment 
maintenance (28%) and the lack of waste for supply (37%) in the field 



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of negative aspects. In this sense, the vast majority refers to the labor 
required for management as the main disadvantage of use, since the 
search for waste outside the property requires time and competes with 
other activities in the production system.

In terms of disadvantages, 65% of the families interviewed in Sertão 
do Pajeú assert that they have no problems or difficulties handling the 
biodigester. They mention three elements regarding the negative aspects: 
dryness or cracking in the piping leading the gas to the stove (15% of the 
sample); water accumulation in the pipe (10%); and a lack of sufficient ani-
mals to produce raw material (10% of the sample). On a smaller scale, they 
cite issues related to insufficient water to feed the equipment, difficulties 
in transporting the manure and damage to the container for filtering the 
gas (drying). This last difficulty was the subject of changes proposed by 
the NGO Diaconia in the filtration system, circumvented by replacing the 
water canister with more resistant PVC material (Diaconia, 2016).

Knopki (2015) describes that biogas can be used to produce elec-
tric, thermal, fuel gas and vehicle fuel, as well as the main character-
istic of its flexibility as an advantage, while the disadvantage is due to 
its complexity related to factors such as controlled production, a value 
chain which is considered complex, and because it is an explosive com-
bustible gas that requires rigorous control, monitoring and investment 
in safety issues.

The group of families with deactivated or unused biodigesters basi-
cally point to three elements as the cause: 
1. that the biodigestor does not work (41%), without specifying the 

reason; 
2. they do not need the biodigester (37%); 
3. the supply is low. 

Of these aspects, items (a) and (c) are related to surmountable caus-
es; however, item (b) points to something directly related to aspects not 
identified before the implementation of the biodigester, which is the 
family’s need for the technology.

Community leaders point out possible causes for disabling the bio-
digester as the lack of interest from the families, the lack of manure to 
feed the biodigester, the lack of maintenance and the lack of technical 
assistance. Families interviewed in Sertão do Pajeú (with longer use of 
biodigesters) highlight two aspects related to not using the biodigester: 
the lack of interest or commitment, as cited by 65%   of respondents; and 
the fact of not having animals to produce raw material, cited by 40%. 

Still regarding item (c), it is observed that the raw material used to 
supply the biodigester basically has two sources: cattle and swine. Con-
sidering that 34% of the families raise goats and sheep, and that 71% 
declare raising birds, the results clearly indicate that the manure from 
these animals is not used as raw material for feeding the biodigester. 
However, it is observed that there is a strong relationship of depen-
dence with raising cattle, as 82% of the families use the manure of these 
animals as an energy source, with part of them (20%) being associated 
with swine manure. The latter is responsible for supplying raw material 
to 7% of the families, and it increases its contribution to 28% in the 
families when associated with cattle (Table 3).

The amount of raw material (manure and water) used is directly 
related to the dynamics of household use. Thus, it was possible to iden-
tify families using 10 kg to 400 kg of raw material per week, with the 
majority (84%) using up to 62 kg per week, with an average of 55 kg 
per family (Graph 1).

Table 2 – Advantages and disadvantages in the use of the biodigester 
presented by families in the municipalities of Bom Conselho, Caetés, Jupi 
and São Caetano, 2019.

Evaluated aspects Absolute Frequency Percentage

Advantages

Economical 78 94.0

Pratical 36 43.4

Abundant gas 10 12.0

Disadvantages

Very hard work 23 27.7

Difficulty collecting waste 31 37.3

Production decreases in winter 2 2

Source: Field research (2020).

Table 3 – Sources of raw material for the biodigester in families in the 
municipalities of Bom Conselho, Caetés, Jupi and São Caetano, 2019.

Source
Absolute 

Frequency
Percentage

Accumulated 
Percentage

Cattle and Swine 17 20.5

Cattle 50 60.2

Cattle and Whey 1 1.2 82

Swine 6 7.2

Uninformed 13 10.8 100

Source: Field research (2020).

Graph 1 – Amount of raw material used to supply the biodigester by 
families in the municipalities of Bom Conselho, Caetés, Jupi and São 
Caetano, 2019.
Source: Field research (2020).



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An important element in the context of families in the Semi-arid 
region is the use of water, as the biodigester requires a lot of water for 
to fully operate, due to the characteristic of biogas production from 
anaerobic fermentation. Data collected on water use indicate an aver-
age of 40 liters per week; however, some families use up to 300 liters of 
water per week. This indicates a proximity to the ratio of 1 kg of raw 
material to 1 liter of water, as recommended in the construction man-
uals for the Sertanejo biodigester.

There is an important competition with the main source for do-
mestic consumption when identifying the water source used, which 
is the cistern, and occurs in 54% of the families. The other sources are 
traditionally employed for different uses, especially for animal water-
ing. However, the contradictory fact is that, despite the fact that most 
families have the cistern as a source of water for feeding the biodigester, 
only 28% claim that the water used is potable (i.e. suitable for human 
consumption), while 77% claim to use water for general purposes, al-
though some may fall into both types.

Plate cisterns have recently gained prominence in family agroeco-
systems, with the implementation of the One Million Cisterns Program 
(P1MC), aiming at capturing and storing rainwater for human con-
sumption. Data indicate that there were 626,791 units implemented 
in all semiarid states until May/2019 (ASA, 2019) under the P1MC. A 
study evaluating the program in 2010 presents some findings which are 
in line with the data presented regarding the cistern water use: 
• the physicochemical characteristics of the waters stored in the cis-

terns indicate that these do not come from rainwater collection, 
but from other alternative sources of supply; 

• 79.54% of the samples were considered unrestricted for use by ben-
eficiary families; 

• the management is adequate in 82.8% of the interviewed families, 
while it is inadequate in 15.1%, with the main problem being the 
poor state of conservation of the cisterns; 

• few households (approximately 19.1%) only use the cistern as the 
main source for domestic water; 

• stored water lasts 12 months in just over a third of households (36.4%), 
while stored water lasts for a maximum of six months for 26.2%. 

This last data has an important meaning considering that the more 
uses that depend on the accumulated water of the cistern, the shorter 
the available water time (Brasil, 2010, p. 151). 

Given the specificities of the Semi-arid region in relation to water 
availability, any technology that presents a demand for consumption 
which will effectively compete with water for domestic use must be 
carefully analyzed. In the specific case of the biodigestor, it deserves 
technical deepening regarding the possibility of its interconnection to 
a system for the reuse of greywater, as a water source for the fermen-
tation process, as well as toilet waste as a way to use organic matter for 
the biodigester.

Part of the water used to facilitate the fermentation process is 
drained in the form of biofertilizer, which can be used as liquid fertil-
izer on crops. The data indicate that this guidance was well captured by 
the set of families, as 84% of the families with a functioning biodigester 
claim to use the biofertilizer for some type of crop. 

Economic and social aspects
It was possible to identify that the biodigesters resulted from the 

relationship that the families maintain with the local Community As-
sociation in 75% of the families, and with the Union of Family Farmers 
Workers in 64% of the cases, indicating that the relationship with these 
organizations takes place simultaneously for some. Some families (9%) 
refer to Cooperativa de Habitação Rural da Agricultura Familiar, Assen-
tamentos da Reforma Agrária e Comunidades Tradicionais LTDA (Ru-
ral Housing Cooperative of Family Farming, Agrarian Reform Settle-
ments and Traditional Communities LTD) (ABEMORAR) the partner 
organization of the NGO Diaconia NGO that carried out the project in 
some municipalities.

The biodigester implementation resulted from the action of a proj-
ect co-financed with public resources through the Caixa Econômica 
Federal Social and Environmental Fund in all the families surveyed, 
and they did not imply practically any financial cost. Only a small part 
claims to have made any investment in paying for the labor of a brick-
layer’s assistant, with values between R$ 150 and R$ 250. This is also 
the narrative of the families in the Pajeú Region, where virtually all 
the biodigesters resulted from the action of the NGO Diaconia. In this 
case, the families claim to have only contributed with labor help such 
as digging the hole and building the biodigester. 

When asked what the cost of a biodigester would be, 71% of the 
sample said they did not know and 29% referred to a cost ranging from 
R$ 2,500 (two thousand five hundred reais) to R$ 8,000 (eight thou-
sand reais), with an average cost of around R$ 3,900 (three thousand 
nine hundred reais). According to the NGO Diaconia (2020), as indi-
cated in the qualified interview with members of its technical team, the 
costs of mason labor, digging the hole, installation, materials and tech-
nical monitoring for a biodigestor unit are around R$ 4,000 (four thou-
sand reais), meaning they are comparable with the average obtained 
according to information from the families. Here it is worth noting 
that a family would take between 48 and 67  months (4 to 5 years) to 
have the investments reversed at a cost of R$ 65 per LPG gas canister by 
taking as a reference this cost per biodigester and the equivalent biogas 
production capacity between 0.92 and 1.28 canisters/month.

The income sources and expenses of families were then analyzed 
in order to understand the composition of the family income, consid-
ering that this is not a deepening of the various elements that make up 
their income, from the perspective brought by Mattos (2017) when dis-
cussing the pluriactivity and multifunctionality of family farming as an 
important element in aggregating income. Thus, the information col-



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lected from the questionnaires enables comparisons and dimensioning 
of the impact of biogas use on the family economy within the proposed 
purpose of the work and drawing parallels with the main sources of 
income, as identified in Table 4. 

A first piece of evidence is that the contributions resulting from 
the Bolsa Família Program and the Rural Retirement Program con-
stitute the two main sources of income, since the two do not add up 
per family. Then there are revenue contributions from agricultural and 
livestock activities, present in 48.2% of families, especially milk (18% 
of families). Furthermore, the participation of non-agricultural activ-
ities (39.8% of families) is not less important, and is mostly related to 
renting labor. 

The survey on the effective use of income had the purpose of iden-
tifying the main expenses of the families, focusing on the main con-
sumption elements and giving total freedom to the families to mention 
the main expenses with the residence. The results enable us to identify 
that spending on food is the most cited (95.2% of families), followed by 
electricity (90.4%) and gas, charcoal and firewood (76%), thus forming 
the tripod of the main expenditure elements cited by families, followed 
by transport (19%), health (16%) and other expenses (12%), as shown 
in Table 5.

The three main energy sources traditionally used for cooking food 
in addition to biogas were analyzed, introduced as an alternative to the 
use of LPG gas. It is noteworthy that the use of LPG gas is still dom-
inant even in the context of families who have adopted the Sertanejo 
biodigester technology for biogas production, as 54% of families still 
use it as the only source of energy for kitchen activities, while another 
25% alternate its use with biogas, which indicates that 79% of families 
maintain their LPG gas consumption after installing the biodigesters. 
Thus, the use of biogas as the only energy source for kitchen activities 
is present in only 17%, but it can be said that 42% of families use this 
energy source, even if one does that less frequently than another, which 
will be detailed further on.

The data presented in Table 5 clearly show that the main expens-
es of families occur with food and health, reaching more than 50% of 
the monthly average. Expenditures on gas, firewood and charcoal rep-
resent only 5% of the average monthly expenditures; however, when 
related to income transfer, retirement and pension programs (Table 4), 
these expenditures represent 8.9% of these revenue sources, increasing 
its impact considerably when compared to the income from the Bolsa 
Família Program, which represented 28.4% of the average obtained. 
These same data can represent 14% and 25.5% when related to the av-

Table 4 – Main sources of income for families in the municipalities of Bom Conselho, Caetés, Jupi and São Caetano, 2019.

Income source Absolute Frequency Relative Frequency
Mean income (by type)

Monthly Annual

Transfer Income/Benefits/Pension 73 95.2% 682.87 8,194.49

Agricultural 40 48.2% 438.23 5,253.80

Non-Agricultural 33 39.8% 239.74 2,876.85

Bolsa Família Program 54 65.1% 215.00 2,795.00

Rural retirement 24 28.9% 998.00 12,974.00

Hired labor 22 26.5% 48.63 583.55

Selling milk 15 18.1% 471.33 5,656.00

Selling cheese 5 6.0% 620.00 7,440.00

Formal employment 3 3.6% 1,154.11 13,849.33

Selling eggs 2 2.4% 57.33 688.00

Cleaning services 1 1.2% 300.00 3,600.00

Selling candy 1 1.2% 100.00 1,200.00

Craftsmanship/handicrafts 1 1.2% 50.00 600.00

Help from relatives 1 1.2% 29.17 350.00

Pension 1 1.2% 998.00 11,976.00

Source: Field research (2020).



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Table 5 – Main expenses of families benefiting from biodigesters in the municipalities of Bom Conselho, Caetés, Jupi and São Caetano, 2019.

Type of expense Absolute Frequency Relative Frequency Mean monthly expense Participation % 

Food 79 95.2% 464.94 37%

Electricity 75 90.4% 49.51 4%

Gas/Coal/Firewood 63 75.9% 61.05 5%

Transport 16 19.3% 118.75 9%

Health 13 15.7% 194.62 15%

Clothes 2 2.4% 10.75 1%

Leisure 1 1.2% 30.00 2%

Other expenses 10 12.0% 333.00 26%

Source: Field research (2020).

erage revenue from agricultural activities and non-agricultural activi-
ties, and expenses on gas, firewood and charcoal, respectively.

According to Diaconia (2020), each family traditionally spends 
about 10% of the minimum monthly wage on the purchase of butane 
gas, which means something around R$ 104.50 in current values. It is 
therefore assumed that the replacement of these sources with the con-
tinuous use of biogas would generate savings for families, and would 
impact them in different ways according to their revenue composition; 
however, by following mathematical logic, there would be greater sig-
nificance for families with a lower monthly revenue average.

The financial impact of using biogas is diluted as alternatives and 
the mean monthly household income increase. Consequently, the use 
of biogas in these cases to replace the use of LPG gas, firewood and 
charcoal generates savings that range from 4 to 5% of the monthly av-
erage, which may not be very attractive for introducing a technology 
such as the biodigester due to its daily management dynamics, as dis-
cussed above.

Table 6 also indicates that there is important room for growth in 
the use of the biodigester from the perspective of reducing expenses 
on gas, firewood and charcoal for families with little income diversifi-
cation, but especially for those who depend on the Bolsa Família Pro-
gram. A considerable percentage still uses butane gas as the only source 
for cooking food, followed by a group of families who associate biogas 
with LPG gas, and finally a smaller group (16.9%), who only use biogas. 
It is noteworthy that when excluding families with the biodigester dis-
abled, the percentage of those who only use biogas to cook food rises 
to 25%. In any case, it is important to highlight that 42% of the total 
sample uses biogas, and again, the percentage of families with active 
biodigesters who use biogas in domestic activities increases to 62.5% 
when extracting the deactivated biodigesters.

The firewood used is removed from the property in 87% of the cas-
es; however, the type of firewood was not studied in depth, although 
some families insisted on informing that it was forest fragments or dry 
firewood, without the need for felling trees. Another important ele-
ment is that 82% of the families say they use firewood weekly, charac-
terizing a very present dynamic in these families. In this sense, a study 
by Specht (2012) indicates that more than 65% of the respondents use 
firewood in their homes in different degrees of intensity, at least once a 
month or every day, and also reveals that 40% of the respondents point 
to saving gas and money among the reasons chosen for regarding the 
use of firewood, and another 40% refer to faster cooking due to its high 
calorific value.

Thus, it is possible to suggest that the best strategy for introducing 
the technology to families with a higher income range may not be by 
convincing them of the economic impact, especially if the use of biogas 
is only associated for cooking food. Therefore, it is necessary to show 
more forcefully the environmental gains that the technology can offer, 
and especially to associate other uses of biogas in the production sys-
tem or in residential activities, which can enable them to expand their 
participation in the reduction of expenses and consequently contribute 
to the family income. 

By making a comparison with the group of families interviewed 
in Sertão do Pajeú, it is observed that the association of biogas with 
other energy sources for cooking food can remain over time, even on 
a smaller scale. This is because 55% of families say they use firewood 
or gas occasionally when it comes to the need to use large utensils for 
cooking food (related to receiving visits), or when there are problems 
with equipment maintenance, which is treated as an emergency. When 
it comes to the use of butane gas associated with biogas, there are re-
ports mentioning the use of 1 canister every two or three months, 1 
to 2 canisters per year or 1 canister every 4 years. In any case, 20% of 



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the families claim to use only biogas, which is a number close to that 
obtained from families in the Agreste region of Pernambuco.

Impact studies of the implementation of 265 biodigesters in the 
Yucatán Mayan communities in Mexico showed a 97% reduction in 
the use of firewood in households, placing biogas as the main energy 
source and identifying an increase in agricultural production by more 
than 60% of the families, resulting from the use of the biofertilizer. A 
small milk producer in Costa Rica implemented its biodigester and re-
placed 40% of the diesel used in its boiler, achieving a return on its 
investment in less than 2 years. ASPROINCA (Asociación de Producto-
res Indígenas y Campesinos de Riosucio Caldas) in Colombia has more 
than 250 biodigesters installed in its operating territory from its own 
revolving fund and with the training of Community Promoters (Her-
rero, 2016).

Work developed by Silva and Correia (2020, p. 8) in Oeste Po-
tiguar found that firewood was the main energy source for 66.7% of 
the families before the biodigester purchase; 33.3% used cooking gas 
and another 14.3% used charcoal. This data reveals how much impact 
introducing the biodigester can have as a gas supplier for cooking food, 
considerably reducing the use of wood from the caatinga for both di-
rect consumption and for charcoal production, as both were present in 
81.9% as power supply.

As shown in Table 7, the average usage time of a gas canister was 
around 30 days, with this period corresponding to 50% of the families; 
others (28%) consume the same amount of gas for a period between 45 
and 60 days. The unit cost of a gas canister ranged between R$ 60/75 in 
the studied period (Nov./18 to Jan./20). However, there is an additional 
cost for 63% of the families, as they buy gas in the city, while 37% buy 
it in the community and may not have the additional transportation 
allowance. When asked about the advantages and disadvantages of us-
ing LPG gas, practicality and agility are the main advantages for 70% 
of families; while the high cost is the main disadvantage for 75% of 
families.

Returning to the study developed by Jiménez and Zambrano 
(2018), which analyzed biogas consumption, it was observed that 
the average daily biogas consumption in a universe of 28 biodigest-

ers (active) in rural communities in the evaluated period (110 days of 
measurement) was 0.37 m³, with 50% of the consumption data found 
between 0.2 and 0.5 m³/day. Regarding the economic impact, the study 
found that the use of firewood was present in 82% of the families at 
a cost of USD 19.50, thus obtaining a total annual value for the use 
of firewood of USD 438.30. Moreover, an investment of USD 306.27 
per year occurred in the case of replacement of the LPG gas. Thus, the 
authors conclude that: obtaining and using biogas as an energy source 
does not represent a monetary cost for families, but rather some help 
which enables them to replace previously used fuels and chemical fer-
tilizers, applying biofertilizer to improve income of their crops. 

Conclusions and Recommendations
The use of social technologies in rural communities in the semi-ar-

id region can meet immediate needs and promote important econom-
ic, social and organizational dynamic impacts on the community, 
enabling these families to understand and commit to environmental 
and social issues in their surroundings, making them local referenc-

Table 6 – Energy sources used by families in the municipalities of Bom Conselho, Caetés, Jupi and São Caetano, 2019.

Energy source Unit Absolute Frequency Percentage Mean monthly consumption Mean monthly expense (R$)

Canister (without Biogas) Canister 45 54.2% 0.86 52.93

Canister (+ Biogas) Canister 21 25.3% 0.76 33.13

Only Biogas Canister 14 16.9% 1.0 -

Coal Kg 38 45.8% 25.0 22.00

Firewood m3 28 33.7% 1.9 -

Source: Field research (2020).

Table 7 – Usage time of the LPG gas canister by families in the 
municipalities of Bom Conselho, Caetés, Jupi and São Caetano, 2019.

Usage time (days) Absolute Frequency Percentage

20 1 1.5

25 1 1.5

30 34 50.0

45 4 5.9

60 15 22.1

90 8 11.8

120 3 4.4

180 1 1.5

365 1 1.5

Source: Field research (2020).



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es. Training actions in the process of implementing these technolo-
gies, with a major role played by NGOs, open spaces for dialogue on 
practices and use of environmentally sustainable technologies, human 
rights, gender relations, and social participation, among others. Thus, 
the decision to use a simple source of clean energy to the detriment 
of the conventional energy matrix is   a political and liberating posture, 
making its agro-ecosystem increasingly self-sustainable and indepen-
dent of external resources. In this perspective, the results presented 
allow us to affirm the hypothesis that the use of the Sertanejo biodi-
gestor social technology provides an increase in the income of farming 
families, influencing a reduction or even replacement of using LPG, 
and representing effective gains proportional to the income level of the 
families, in addition to biofertilizer production used in temporary and 
permanent crops, notably in forage cactus cultivation. 

The hypothesis that the non-use or deactivation of the biodigest-
er is related to the lack of raw material, requirements in equipment 
maintenance and/or shortage of labor to maintain the equipment is 
also confirmed, notably in relation to the raw material, as this is the 
reason most pointed out as the cause of the continuous non-use of the 
technology.

The existence of technology protection mechanisms is considered 
important, given the possibility of a loss of confidence in the proposed 
biodigester model due to its implementation without due care.

Thus, the following is recommended: not to deploy a biodigester 

in family units without livestock activities, under penalty of creating 

dependence on external sources; carry out preliminary studies on the 

family’s demand for biogas, relating it to the potential of biogas pro-

duction from the existing herd in order to establish a dynamic in ac-

cordance with the expected consumption; strengthen the arguments of 

economic impact for low-income families and highlight the arguments 

of environmental impact for families with more permanent sources 

of income, especially when not associated with agricultural activities; 

encourage the use of biogas associated with other activities in the pro-

duction system, especially those dependent on conventional electricity, 

considering the construction of a biodigester with greater production 

capacity and using generators adapted to biogas use; establish dia-

logues with public agencies for technical assistance and rural extension 

and credit agents in order to incorporate the biodigester technology in 

financing lines from the environmental sustainability perspective; and 

always seek technical guidance for implementing the biodigester. It is 

a greatly useful device with environmental importance, but it needs to 

be well dimensioned and the installation of the gas pipes must be done 

by a professional with technical knowledge in the area. 

Contribution of authors:
Souza, R.A.: Conceptualization, Methodology, Validation, Formal analysis, Research, Investigation, Resources, Writing — original draft.  Lyra, M.R.C.C.: 
Supervision, Visualization, Writing — original draft, Writing — review & editing, Project administration, Funding acquisition. Carvalho, R.M.C.M.O.: 
Supervision, Writing — original draft, Writing — review & editing. Araújo Filho, J.C.A.F.: Conceptualization, Formal analysis, Methodology, Supervision, 
Visualization, Writing — original draft, Writing — review & editing.

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