Air quality in swine growing and finishing facilities with different building typologies

Cecchin, Daiane; Campos, Alessandro T.; Cruz, Vasco F. da; Sousa, Francine A.; Amaral, Pedro I. S.; Yanagi, Tadayuki

doi:10.1590/1807-1929/agriambi.v21n5p339-343

ABSTRACT

The objective of this study was to evaluate the concentration of gases in three swine growing and finishing facilities with different building typologies, regarding floor and dividers. The experiment compared three treatments: pen with water depth, pen with partially slotted floor on the sides, and pen with partially slotted floor on sides and in the center. Measurements of instantaneous concentrations of ammonia (NH₃ ppm) and carbon dioxide (CO₂ ppm) were taken at animal level. The levels of sound pressure (dB) at animal level and at 1.50 m from the floor were also recorded. It was observed that the pen with water depth was the one with the highest average concentration of NH₃. Although there was a significant difference in CO₂ concentrations, the observed values are within the limits allowed by the Brazilian standards; thus, it is assumed that the facilities do not cause discomfort in relation to CO₂ levels. The pen with water depth possibly caused discomfort to the animals, since the NH₃ concentration was above the values that can cause problems to the animals, according to the recommendation of the literature. There was no influence of the type of pen on the sound pressure at any time.

Key words:
animal welfare; rural buildings; gas concentration; sound pressure

RESUMO

O objetivo do trabalho foi avaliar a concentração de gases em três instalações de crescimento e terminação para suínos, com tipologias construtivas diferentes no que tange ao piso e divisórias. Compararam-se três tratamentos: baia com lâmina d’água, baia com piso parcialmente vazado nas laterais e baia com piso parcialmente vazado nas laterais e no centro. Foram feitas medições das concentrações instantâneas de amônia (NH₃, ppm) e dióxido de carbono (CO₂, ppm) a nível dos animais; também foram registrados os níveis de pressão sonora (dB) a nível dos animais e a 1,50 do piso. Observou-se que a baia com lâmina d’água foi a que apresentou o maior valor médio de concentração de NH₃. Apesar de haver ocorrido diferenças significativas nas concentrações de CO₂, os valores encontrados estão dentro dos limites permitidos pelas normas brasileiras, presumindo-se, assim, que as instalações não ocasionam desconforto em relação aos níveis de CO₂. A baia com lâmina d’água demostrou proporcionar um possível desconforto aos animais, com nível de concentração de NH₃ acima de valores que já podem acarretar problemas aos animais de acordo com o preconizado pela literatura. Não foi observada influência do tipo de piso da baia sobre a pressão sonora em nenhum horário.

Palavras-chave:
bem-estar; construções rurais; gases; pressão sonora

Introduction

Confined swine are maintained in pens most of their lives; thus, the housing must provide adequate conditions of comfort to the animals. Therefore, it becomes important to search for new information on the different types of floors used in these pens.

Various gases are formed inside the facilities, regardless of the utilized production system, varying only the concentrations, and depending on the concentrations, these gases can be harmful and even lethal to the animals. Gases such as ammonia (NH₃), hydrogen sulfide (H₂S) and carbon dioxide (CO₂) are the most present inside swine facilities (Amâncio et al., 2013Amâncio, D.; Furtado, D. A.; Nascimento, J. W. do; Santos, L. D. F. dos. Avaliação da qualidade do ar e ambiente térmico em maternidade suinícola no semiárido paraibano. Revista Educação Agrícola Superior, v.28, p.10-14, 2013. https://doi.org/10.12722/0101-756X.v28n01a02
https://doi.org/10.12722/0101-756X.v28n0... ). Ammonia is the most important gas, because it can occur at very high levels, irritating the respiratory system, leading to behavioral and physiological alterations, reduction in food consumption and weight gain, and possibly affecting the health of animals and workers (Paulo et al., 2009Paulo,, R. M.; Tinôco, I. F. F.; Oliveira,, P. A. V.; Souza, C. F.; Baêta, F. C.; Cecon, P. R. Avaliação da amônia emitida de camas sobrepostas e piso concretado utilizados na criação de suínos. Revista Brasileira Engenharia Agrícola Ambiental, v.13, p.210-213, 2009. https://doi.org/10.1590/S1415-43662009000200016
https://doi.org/10.1590/S1415-4366200900... ; Kiefer et al., 2010Kiefer, C.; Moura, M. S. D.; Silva, E. A. D.; Santos, A. P. D.; Silva, C. M.; Luz, M. F. D.; Nantes, C. L. Respostas de suínos em terminação mantidos em diferentes ambientes térmicos. Revista Brasileira de Saúde e Produção Animal, v.11, p.496-504, 2010.).

The quantification of gas production in production systems is a global concern, since it can affect the environment, health of people involved in the production processes and even alter animal performance (Inoue et al., 2012Inoue, K. R. A.; Tinôco, I. de F. F.; Cassuce, D. C.; Graña, A. L.; Bueno, M. M.; Tinôco, B. F. Análise da concentração de amônia em galpões de frangos de corte submetidos a diferentes dietas. Engenharia na Agricultura, v.20, p.19-24, 2012.).

Research conducted with swine has demonstrated that the study of vocalization and sound pressure levels is an innovative and non-invasive method that can indicate the responses of the animal in adverse situations (Borges et al., 2010Borges, G.; Miranda, K. O. S.; Rodrigues, V. C.; Risi, N. Uso da geoestatística para avaliar a captação automática dos níveis de pressão sonora em instalações de creche para suínos. Engenharia Agrícola, v.30, p.377-385, 2010. https://doi.org/10.1590/s0100-69162010000300002
https://doi.org/10.1590/s0100-6916201000... ; Castro et al., 2013Castro, J. O.; Ferreira, R. A.; Campos, A. T.; Yanagi Júnior, T.; Tadeu, H. C. Uso de ardósia na construção de celas de maternidade para suínos: II - Ambiente térmico e avaliação dos ruídos. Engenharia Agrícola, v.33, p.37-45, 2013. https://doi.org/10.1590/S0100-69162013000100005
https://doi.org/10.1590/S0100-6916201300... ; Moura et al., 2008Moura, D. J.; Silva, W. T.; Nääs, I. A.; Tolón, Y. A.; Lima, K. A. O.; Vale, M. M. Real time computer stress monitoring of piglets using vocalization analysis. Computers and Electronics in Agriculture, v.64, p.11-18, 2008. https://doi.org/10.1016/j.compag.2008.05.008
https://doi.org/10.1016/j.compag.2008.05... ). These methodologies make possible to evaluate the situation of the environment where the animals are (Miranda et al., 2012Miranda, K. O. S.; Borges, G.; Menegale, V. L. C.; Silva, I. J. O. Efeito das condições ambientais no nível de ruído emitido por leitões. Engenharia Agrícola, v.32, p.435-445, 2012. https://doi.org/10.1590/S0100-69162012000300003
https://doi.org/10.1590/S0100-6916201200... ), since the vocalization is the expression of their specific state (Dupjan et al., 2008Dupjan, S.; Schon, P.; Puppe, B.; Tuchscherer, A.; Manteuffel, G. Differential vocal responses to physical and mental stressors in domestic pigs. (Sus scrofa). Applied Animal Behaviour Science, v.114, p.105-115, 2008. https://doi.org/10.1016/j.applanim.2007.12.005
https://doi.org/10.1016/j.applanim.2007.... ).

In this context, this study aimed to evaluate the concentration of gases and the sound pressure in three swine growing and finishing facilities with different building typologies regarding the floor and dividers.

Material and Methods

The study was carried out in a commercial swine farm (Granja Niteroi) (21º 11’ 37” S; 45º 02’ 49’’ W; 918 m), in the municipality of Lavras-MG, Brazil, from June to September 2014, during the winter.

The climate of the region, according to Köppen’s classification, is Cwa, i.e., rainy temperate (mesothermal) with dry winter and rainy summer, subtropical.

The evaluated raising system was intensive confinement, in which the animals do not have access to the outside of the facilities. The thermal environment and air quality of facilities with swine in growing and finishing stages were evaluated.

The animals were housed in pens as follows: with mean weight of 28.69 kg (pens with water depth, WDP); 28.75 kg (pens with partially slotted floors on the sides, SLS) and with 28.5 kg (pens with partially slotted floor on sides and in the center, SLC). The animals remained in the pens during the growing and finishing stages, reaching final mean weights of 83.47 kg (WDP pen), 85.47 kg (SLS pen) and 87.67 kg (SLC pen).

The animals were housed in masonry barns covered with fiber-cement roofing, supporting structures in reinforced concrete, concrete floor and East-West orientation. Each pen was equipped with two automatic feeders and four nipple drinkers, with total area of 72 m² (8 x 9 m), ceiling height of 3 m, containing 72 animals each. The WDP pen had, on one of its sides, a lowering on the concrete floor (1 m wide and 10 cm deep), filled with water, and was fenced by masonry dividers with ceramic bricks covered with a layer of concrete render and painted in white. The SLC pen had dividers made of steel wire ropes, ceiling height of 3 m and concrete floor, with sides made of slotted precast concrete plates. The SLS pen had masonry dividers with a layer of cement render painted in white, concrete floor, with sides and center made of slotted concrete plates. Figure 1 shows the arrangement of the pens through the floor plan.

Figure 1
Floor plan of the pens (WDP: Water depth, SLS: slotted floor on the sides and SLC: slotted floor in the center and sides)

Data relative to the ambient thermal comfort in the pens and outside were automatically collected using data loggers (Hobo, model U12-013), with accuracy of ± 0.5 oC. These devices recorded the dry bulb temperature, relative air humidity and black globe temperature in intervals of five minutes. The data loggers were positioned inside the facilities at a height of 1.20 m from the floor.

The concentration of the ammonia gas (NH₃) was measured using a Testo^® sensor, with “electrochemical principle”, 1-ppm resolution and accuracy of ±1 ppm, which detects the instantaneous concentration in a measuring range from 0 to 100 ppm, whose cell was calibrated in a company registered by Inmetro. Each collection of carbon dioxide (CO₂) was performed using a Testo^® sensor, model 535, with “infrared principle”, 1-ppm resolution and accuracy of ±50 ppm, which detects the instantaneous concentration in a measuring range from 0 to 10,000 ppm. The concentrations of the gases were measured at three different times of the day (9, 12 and 15 h) inside each pen.

The mean level of sound pressure (dB) was obtained using a decibel meter (DEC-460, Instrutherm). The instrument has resolution of 0.1 dB and accuracy of ±1.5 dB, operating in the compensation scale “A”. Noise data were collected at two heights (animal level (0.60 m) and 1.50 m from the floor) at three times of the day (9, 12 and 15 h), in the center of the pen.

The obtained results of the noises were used to make boxplot graphs considering the values observed at animal level, using the statistical package Minitab^® 16.1.0.

The data relative to the thermal environment were subjected to analysis of variance using the F test and the means were then compared by Tukey test at 0.05 probability level. For this, the analysis was conducted in a randomized block design with split plots, in which the types of floor represented the plots, the evaluation times represented the subplots and the days of collection represented the blocks. The results were obtained using the statistical program Sisvar 5.3 (Ferreira, 2008Ferreira, D. F. Sisvar: Um programa para análises e ensino de estatística. Revista Científica Symposium, v.6, p.36-41, 2008.).

The gases (NH₃ and CO₂) and noises, due to the nonparametric character of the variables, were subjected to descriptive analysis and the medians of treatments were compared by the confidence interval at 95% significance level (CI = 95%). The results were obtained using the statistical program Minitab^® 16.1.0.

Results and Discussion

There were statistical differences (p < 0.05), based on the confidence interval of the median (Table 1), in concentrations of NH₃ and CO₂, which varied between pens and between the analyzed times. Regarding the times, in the WDP pen, there were differences for the gases, which showed the same trend of results, with an increase in the afternoon period. At 12 and 15 h, there were the highest values, statistically equal, followed by the value found at 9 h, which was also statistically equal to that of 12 h.

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Table 1
Concentrations of gases (ppm) observed along the day in swine growing and finishing facilities with floors with water depth (WDP), slotted on the sides (SLS) and slotted in the center and sides (SLC)

According to Popescu et al. (2010)Popescu, S.; Stefan, R.; Borda, C.; Lazar, E. A.; Sandru, C. D.; Spinu, M. The ammonia concentration in growing-finishing pig houses. Lucrări Ştiinţifice Medicină Veterinară, v.43, p.320-326, 2010., NH₃ production and release are generally influenced by temperature and relative air humidity. The relative air humidity in the WDP pen was the highest in comparison to the others (Table 2), which explains the highest NH₃ concentrations found in this treatment. The black globe temperature in the WDP pen was the lowest one, in the comparison to all treatments.

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Table 2
Mean values of environmental variables observed during the evaluated period, along the day, in swine growing and finishing facilities with floors with water depth (WDP), slotted on sides (SLS) and slotted in the center and sides (SLC)

Regarding the ambient temperature and black globehumidity index (BGHI), the values in the WDP pen did not differ from those observed in the SLS, being lower than those found in the SLC. In the present study, the observed BGHI values are below the one found by Turco et al. (1998)Turco, S. H. N.; Ferreira, A. S. F. da C.; Aguiar, M. A.; Cecon, P. C.; Araújo, G. G. L. Avaliação térmica ambiental de diferentes sistemas de acondicionamento térmico em maternidades suinícolas. Revista Brasileira de Zootecnia, v.27, p.974-981, 1998., who mentioned that the upper limit condition of thermal comfort of the BGHI for adult swine is 72.

The SLS pen showed statistically equal concentrations of NH₃ and CO₂ between the times, while SLC exhibited equal concentrations between the times for the gas NH₃.

The observed NH₃ concentrations are below the recommendation for animals by the norms - Commission Internationale du Gene Rural - CIGR (2002)CIGR - Commission Internationale du Génie Rural. Climatization of animal houses. Heat and moisture production at animal and house levels. Horsens: Research Centre Bygholm, Danish Institute of Agricultural Sciences, 2002. 45p., of 20 ppm. NIOSH (1996)NIOSH - National Institute of Occupational Safety and Health. Safety in swine production systems. Raleigh: Cooperative Extension Service Publications. n. PIH - 104, 1996. <http://infohouse.p2ric.org/ref/03/02760.htm.
http://infohouse.p2ric.org/ref/03/02760.... considers that the maximum concentration of the gas must not exceed 25 ppm, but at certain times (12 and 15 h) in the WDP pen, the NH₃ concentration exceeded the limit recommended by Heber et al. (2002)Heber, A.; Jones, D.; Sutton, A. Indoor air quality: Controlling ammonia gas in swine buildings. Purdue University Cooperative: Extension Service. 2002. <https://www.extension.purdue.edu/extmedia/IAQ/IAQ-1.pdf>. 18 Mar. 2015.
https://www.extension.purdue.edu/extmedi... , who consider that concentrations above 10 ppm can harm animal health and growth. Barker et al. (2002)Barker, J.; Curtis, S.; Hogsett, O.; Humenik, F. Safety in swine productions systems. Raleigh: Waste Quality & Waste Management, North Carolina Cooperative Extension Service, 2002. 12p. report that the exposure to concentrations above 6 ppm lead to mucosal irritation and exposures to more than 20 ppm can cause eye irritation and respiratory problems. In the present study and at all times of evaluation, in the WDP and SLS pen, the NH₃ levels were higher than 6 ppm, indicating a probable discomfort to the animals.

Amâncio et al. (2013)Amâncio, D.; Furtado, D. A.; Nascimento, J. W. do; Santos, L. D. F. dos. Avaliação da qualidade do ar e ambiente térmico em maternidade suinícola no semiárido paraibano. Revista Educação Agrícola Superior, v.28, p.10-14, 2013. https://doi.org/10.12722/0101-756X.v28n01a02
https://doi.org/10.12722/0101-756X.v28n0... , studying the NH₃ concentration in swine nursery during the winter, although with slightly different typologies than growing and finishing, also observed significant difference in the mean concentration of this gas for the different times evaluated, with higher means in the last times of evaluation (13 to 15 h).

Regarding the CO₂ levels in the present study, the SLC pen also showed differences between the times and the highest concentrations were recorded at 9 and 15 h, with a reduction in CO₂ concentration at 12 h. This pen is characterized for being the most open (slotted floors and side dividers made of steel wire ropes), allowing a greater renewal of the air in the micro-environment, notably in this hotter period, proportionally reducing the levels of CO₂. Thus, the lowest CO₂ concentrations occurred at 12 and 15 h (482 and 541 ppm, respectively) in the SLC pen, compared with the others.

For the time of 9h, there was no statistical difference in the concentration of the gases between the studied pens. For the times of 12:00 and 15:00 h, the NH₃ concentration was higher in the WDP pen, compared with the SLC, but the values in the SLS pen were statistically equal to those in WDP and SLC. For CO₂, the SLC pen showed lower concentrations at 12 and 15 h, compared with the others.

The CO₂ concentrations found in the present study are lower than those that can harm animal and human health, and the norm NR-15 (Brasil, 1978Brasil. Ministério do Trabalho e Emprego. Portaria nº 3.214, de 8 de junho de 1978. Normas regulamentadoras de segurança e saúde no trabalho - NR-15: Atividades e operações insalubres. Brasília, 1978. <http://www.mte.gov.br/legislacao/normas_regulamentadoras/nr_15.pdf>. 12 Out 2014.
http://www.mte.gov.br/legislacao/normas_... ) establishes the maximum limit of 3,900 ppm for workers. According to Larry et al. (1994)Larry, D. J.; Steve, P.; William, G. B. Troubleshooting swine ventilation systems. West Lafayette: Purdue University Cooperative Extensoin Service, 1994. 32p., the CO₂ is considered as excessive when the concentration is above 3,000 ppm and, for concentrations of up to 5,000 ppm, it can be tolerated for brief periods by animals.

Sousa et al. (2014)Sousa, F. A.; Campos, A. T.; Amaral, P. I. S.; Castro, J. O.; Yanaji Júnior, T.; Veloso, A. V.; Ferreira, S. V.; Cecchin, D. Ambiência aérea e temperatura da cama sobreposta em instalação para suínos. Journal of Animal Behaviour and Biometeorology, v.2, p.109-116, 2014. https://doi.org/10.14269/2318-1265/jabb.v2n4p109-116
https://doi.org/10.14269/2318-1265/jabb.... , evaluating CO₂ concentrations, but using overlapping beds, for swine in the finishing stage, also obtained results below the concentration that can cause damages to animal health, at all evaluated times (9 h 00 min; 11 h 30 min; 14 h 00 min and 16 h 30 min).

In the present study, there was no statistical difference in the confidence interval and median at 95% probability level in the sound pressure (Table 3) for any of the times or heights (animal level and 1.50 m from the floor).

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Table 3
Noise level measured in swine growing and finishing facilities with floor with water depth (WDP), slotted on sides (SLS) and slotted in the center and sides (SLC)

The means observed both at animal level and 1.5 m from the floor for all treatments and all evaluated times are within the range of noise emission tolerance established by the norm NR-15 (Brasil, 1978Brasil. Ministério do Trabalho e Emprego. Portaria nº 3.214, de 8 de junho de 1978. Normas regulamentadoras de segurança e saúde no trabalho - NR-15: Atividades e operações insalubres. Brasília, 1978. <http://www.mte.gov.br/legislacao/normas_regulamentadoras/nr_15.pdf>. 12 Out 2014.
http://www.mte.gov.br/legislacao/normas_... ), of 85 dB for workers, demonstrating that there are no insalubrious conditions for the workers and that they can stay for longer periods under the conditions presented in the study. Tolon et al. (2010)Tolon, Y. B.; Baracho, M. S.; Nääs, I. A.; Rojas, M.; Moura, D. J. Ambiência térmica aérea e acústica para reprodutores suínos. Engenharia Agrícola, v.30, p.1-13, 2010. https://doi.org/10.1590/S0100-69162010000100001
https://doi.org/10.1590/S0100-6916201000... mention that, because there are no specific norms that evaluate the limit of tolerance to the noises emitted by the animals, the same noise levels indicated for humans have been adopted as ideal.

Sampaio et al. (2005)Sampaio, C. A. P.; Nääs, I. A.; Nader, A. Gases e ruídos em edificações para suínos: Aplicação das normas NR-15, CIGR e ACGIH. Engenharia Agrícola, v.25, p.10-18, 2005. https://doi.org/10.1590/S0100-69162005000100002
https://doi.org/10.1590/S0100-6916200500... claim that the behavior of the noise emitted by the animals along the day is related to the higher or lower well-being for swine. Therefore, since there was no difference between the noise levels, with values below the recommendations and BGHI within adequate levels, it can be assumed that the animals were in a comfort condition.

Conclusions

There was no significant difference in CO₂ concentrations for the different typologies of facilities.
The pen with water depth led to a possible discomfort to the animals, with NH₃ concentration above the values that could cause problems.
There was no influence of the analyzed building typologies of the pens on the sound pressure, at any of the evaluated times.

Acknowledgments

To the Coordination for the Improvement of Higher Education Personnel (CAPES), for granting the scholarship of the Doctoral Sandwich Program Abroad (PSDE - process 99999.010665/2014-05), to the Minas Gerais Research Support Foundation (FAPEMIG) and to the National Council for Scientific and Technological Development (CNPq), for the financial support to the projects.

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» https://doi.org/10.12722/0101-756X.v28n01a02
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» https://www.extension.purdue.edu/extmedia/IAQ/IAQ-1.pdf
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» https://doi.org/10.1590/S1415-43662009000200016
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Sampaio, C. A. P.; Nääs, I. A.; Nader, A. Gases e ruídos em edificações para suínos: Aplicação das normas NR-15, CIGR e ACGIH. Engenharia Agrícola, v.25, p.10-18, 2005. https://doi.org/10.1590/S0100-69162005000100002
» https://doi.org/10.1590/S0100-69162005000100002
Sousa, F. A.; Campos, A. T.; Amaral, P. I. S.; Castro, J. O.; Yanaji Júnior, T.; Veloso, A. V.; Ferreira, S. V.; Cecchin, D. Ambiência aérea e temperatura da cama sobreposta em instalação para suínos. Journal of Animal Behaviour and Biometeorology, v.2, p.109-116, 2014. https://doi.org/10.14269/2318-1265/jabb.v2n4p109-116
» https://doi.org/10.14269/2318-1265/jabb.v2n4p109-116
Tolon, Y. B.; Baracho, M. S.; Nääs, I. A.; Rojas, M.; Moura, D. J. Ambiência térmica aérea e acústica para reprodutores suínos. Engenharia Agrícola, v.30, p.1-13, 2010. https://doi.org/10.1590/S0100-69162010000100001
» https://doi.org/10.1590/S0100-69162010000100001
Turco, S. H. N.; Ferreira, A. S. F. da C.; Aguiar, M. A.; Cecon, P. C.; Araújo, G. G. L. Avaliação térmica ambiental de diferentes sistemas de acondicionamento térmico em maternidades suinícolas. Revista Brasileira de Zootecnia, v.27, p.974-981, 1998.

Publication Dates

Publication in this collection
May 2017

History

Received
02 Aug 2016
Accepted
13 Jan 2017

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» https://doi.org/10.1590/S0100-69162005000100002

[19] Sousa, F. A.; Campos, A. T.; Amaral, P. I. S.; Castro, J. O.; Yanaji Júnior, T.; Veloso, A. V.; Ferreira, S. V.; Cecchin, D. Ambiência aérea e temperatura da cama sobreposta em instalação para suínos. Journal of Animal Behaviour and Biometeorology, v.2, p.109-116, 2014. https://doi.org/10.14269/2318-1265/jabb.v2n4p109-116
» https://doi.org/10.14269/2318-1265/jabb.v2n4p109-116

[20] Tolon, Y. B.; Baracho, M. S.; Nääs, I. A.; Rojas, M.; Moura, D. J. Ambiência térmica aérea e acústica para reprodutores suínos. Engenharia Agrícola, v.30, p.1-13, 2010. https://doi.org/10.1590/S0100-69162010000100001
» https://doi.org/10.1590/S0100-69162010000100001

[21] Turco, S. H. N.; Ferreira, A. S. F. da C.; Aguiar, M. A.; Cecon, P. C.; Araújo, G. G. L. Avaliação térmica ambiental de diferentes sistemas de acondicionamento térmico em maternidades suinícolas. Revista Brasileira de Zootecnia, v.27, p.974-981, 1998.

Brasil

Brasil

Air quality in swine growing and finishing facilities with different building typologies

Qualidade do ar em instalações para suínos em crescimento e terminação com diferentes tipologias construtivas

ABSTRACT

RESUMO

Introduction

Material and Methods

Results and Discussion

Conclusions

Acknowledgments

Literature Cited

Publication Dates

History