1. Introduction
Considerable attention has long been paid to stressful situations and conditions for farm animals [
1,
2]. Animals’ welfare can be threatened by many factors; exposure to adverse climatic conditions can also lead to stress conditions [
3].
The indoor environment in animal houses is characterized by a significant biological load, which causes a large production of harmful substances. In terms of air cleanliness, in addition to gaseous pollutants, airborne dust is an important pollutant. The concentration of airborne dust is greatly influenced by the animal species, the housing technology, the size of the barn, and the number of housed animals [
4,
5,
6,
7,
8,
9,
10]. The highest airborne dust concentration is found in barns for poultry and pigs; in sheds for cattle, it is usually lower [
4,
5,
6,
7,
8,
9]. Therefore, research on the cleanliness of the indoor environment and emissions from livestock buildings pays less attention to airborne dust in buildings for cattle [
11].
The number of people who develop asthma and allergies grows each year [
12]. Research [
13] shows the severity of cattle farm allergies in young farmers. Research on farms [
14] showed allergy symptoms related to cattle breeding (upper respiratory tract, asthma, and skin). Due to the nature of farm work, the greatest risk to farmers’ health is biological hazards in the form of numerous microorganisms and their metabolites, plant particles, and animal particles contained in organic dust [
15,
16].
Published studies on dust exposure among livestock farmers show that the workforce in these industries is overexposed and at risk of developing respiratory diseases. Thus, there is an urgent need to focus on exposure in agriculture to protect farmers and others working in these and related industries from developing respiratory diseases and allergies [
17].
Airborne dust has a harmful effect on the health of workers [
4,
6,
7,
8,
9,
18,
19], but it can also have a negative effect on housed animals [
4,
5,
6,
7,
8,
9,
20,
21,
22,
23,
24,
25]. In terms of their effect on the organism, dust particles in animals’ houses are classified as airborne dust without a fibrogenic effect but with an irritating effect. The irritating effect can affect not only the respiratory tract but also the mucous membranes of the eyes or skin. The irritating effect is caused by their composition, as they are dust particles of animal origin (feathers, wool, fur, and other animal dust) and plant origin (hay, straw, grain, feed mixtures, etc.) [
4,
5,
6,
7,
8,
9].
Considerable attention is paid to issues of microbiology in terms of nutrition, production quality, and animal health [
20,
21,
22]. Microorganisms (bacteria, fungi, fungal spores, etc.) are also abundant in the barn dust, whose effect on the health of the organism can be harmful [
4,
5,
6,
7,
8,
9,
11,
26,
27,
28,
29,
30].
The size of the airborne dust particles is important. From the entire size spectrum of solid particles, particles over 100 μm are removed very quickly by gravity. Smaller particles, and especially respirable particles, remain in the air longer [
31,
32,
33,
34]. Since the health risks and penetration of particles into the respiratory tract depend on their aerodynamic properties, particles are classified according to them.
Large airborne dust particles, which tend to settle more quickly, are therefore not as significant a threat to humans as fine particles [
31,
32,
33,
34,
35,
36,
37,
38]. Small particles can stay in the air longer and can easily enter the respiratory tract. Therefore, a classification is introduced that divides airborne dust particles based on their size and the depth of penetration into the respiratory system.
Airborne dust particles are divided into fractions [
32,
33,
34,
35]:
- −
Inhalable fraction: occurs in the air and is inhaled through the nose or mouth. If the size of dust particles exceeds 10 μm, then such particles are attached mainly in the upper respiratory tract;
- −
Thoracic fraction: of the total inhaled airborne dust, the fraction that penetrates beyond the larynx after inhalation;
- −
Respirable fraction: entering areas of the respiratory system that do not have cilia-type epithelium. Such particles do not exceed 4 μm; they penetrate into the alveoli and are therefore very dangerous.
To clarify measurement and assessment methods, in addition to the total airborne dust mass concentration (TDC), dust particles are divided according to size into PM10, PM4, PM2.5, and PM1 fractions.
The respirable fraction is taken in the event of airborne dust with a predominantly fibrogenic effect. The sources of airborne dust in barns are primarily housed animals, feed, and bedding, and therefore airborne dust in barns is primarily organic [
4,
5,
6,
7,
8,
9], which does not pose a risk of fibrogenic effects. Determining other fractions may be justified for research and special tasks.
Occupational exposure limits (OELs) are regulatory values (concentration limits) that indicate levels of exposure that are considered to be safe (health-based) for a hazardous contaminant in the air of a workplace.
According to [
35], this type of airborne dust has only irritating effects (poultry feathers, particles of feed, straw, and sawdust). Occupational Exposure Limits important for animal houses are for animal dust: feathers (4 mg·m
−3), wool, fur, and other animal dust (6 mg·m
−3), for straw, and cereals (6 mg·m
−3).
Measured airborne dust inside this type of building is not aggressive; therefore, as a criterion for comparative evaluation of the measured values, it could be interesting to use the limit level of outdoor airborne dust. According to the Air Protection Act No. 201/2012 [
37], the PM
10 limit value in 24 h is 50 µg·m
−3, the 1-year limit value is 40 µg·m
−3, and the 1-year limit value for PM
2.5 is 25 µg·m
−3. According to [
38], the limit level for PM
10 is 50 µg·m
−3 for a 24 h exposure period and 25 µg·m
−3 for an annual exposure period; the limit level for PM
2.5 is 25 µg·m
−3 for a 24 h exposure period and 8 µg·m
−3 for an annual exposure period.
According to [
6,
38,
39], measurement of the PM
1 fraction is important and should also have been considered in monitoring programs and possibly in future regulations because the magnitude of this fraction might not be negligible. Thus, differential particle sampling is encouraged, even going down to the ultra-fine fraction. In summary, research should address particle composition and sources, particle size, PM levels, and the factors influencing these.
The time of day or night and the technological operations and activities that take place in the animals’ houses also influence the concentration of airborne dust in the buildings [
4,
40,
41,
42,
43]. Dust concentration will increase significantly, e.g., during bedding or feeding [
4,
8,
9,
40,
41,
42,
43,
44]. The season of the year and high air humidity also influence airborne dust concentration [
4,
41,
43]. Higher airborne dust concentrations were therefore found inside the buildings for farm animals in the winter, and researchers from northern Europe pay a lot of attention to measuring airborne dust [
4,
10,
27,
28,
41,
43].
Light airborne dust particles also spread to the surroundings of farms. Research on airborne dust on cattle farms is therefore conducted not only inside the barns but also in the paddock during the summer [
45].
The experiments with dairy cows were conducted in an air-conditioned cowshed. The effect of the regulated ionic microclimate on the emission of PM
10 dust particles was positive, and airborne dust concentration was slightly reduced [
46].
The aim of this research is to demonstrate that the size composition of airborne dust fractions in dairy cattle barns is important to examine in more detail, down to the smallest particles, including the factors that influence this composition.
2. Materials and Methods
2.1. Description of Buildings Used for Research
This research was carried out on several farms located in the Czech Republic. The Czech Republic lies in a mild climate zone that is characterized by the alternation of four seasons. Due to its location in the central part of the European mainland, the influence of the ocean and the westerly direction of airflow prevail here [
47]. In the territory of the Czech Republic, the long-term monthly average air temperature has a simple annual pattern with a minimum mainly in January and a maximum mainly in July and August. The average air temperature in the Czech Republic from 1961 to 1970 in July was 16.7 °C and in August 15.8 °C, and from 2012 to 2021 in July it was 19.9 °C and in August 18.3 °C [
48]. Relative air humidity ranges from 60–80% on an annual average. It is significantly influenced by daily temperatures and the amount of precipitation. The lowest is usually between April and August.
Airborne dust concentration was measured during the summer when no technological operations such as milking, feeding, cleaning, or bedding with straw were taking place in the barns.
For this research, all barns investigated are in the same climatic region, typical for agricultural conditions. The buildings for dairy cattle housing were selected in such a way that the causes of possible differences in the airborne dust concentrations inside the investigated buildings could be identified and shown. Barns thus represent the most common types of agricultural buildings for housing dairy cows and other categories of cattle in the Czech Republic; however, the building structure, building materials, and technological equipment for housing differ. The numbers of housed animals are also different, which, however, also corresponds to their use in the operation of dairy cattle farms.
The research included the measurement and evaluation of indoor airborne dust in buildings: dairy production cowsheds for lactating cows LC (number of housed animals inside the building): LC 100, LC 113, LC 116, LC 210, LC 440, barn for dry cows DC 23, cowshed for maternity cows MC 27, calf hutch CaH 1, barn for calves CaB 36, and for comparison, also in one barn with beef cows and calves BC 38.
Summary information about the researched barns and selected construction and operational parameters is processed in
Table 1.
Dairy production cowsheds for lactating cows (LC 100) are used for housing 100 Jersey cows in cubicles with straw bedding. The roof with a central ridge slot is covered by plastic plates, partly completed by translucent fiberglass; gable walls are partly made from wood and partly from PVC mesh; side walls are made from PVC mesh, which can be covered by the vertically movable PVC tarpaulin.
Old cowshed LC 113, with 113 Holstein dairy cows, has stanchion housing with straw bedding. Ventilation is through slightly open windows and doors. In addition to dairy cows, calves are also housed in the barn in the first period after giving birth for approximately 2 weeks, near the lactating dairy cow—their mother.
Old cowshed for lactating cows LC 116 with a capacity of 116 dairy cows is constructed from massive stone and brick walls. It is used for housing 80 Jersey cows in individual cubicles with straw bedding. The natural ventilation of the building is through partially open windows and doors.
Modern cowshed LC 210 with loose housing technology for 210 Holstein lactating cows has comfort cubicles covered by separated dried manure solids as bedding. Longitudinal walls are made of woven fabric mesh and variable side curtains, which, together with a ventilation roof ridge slot, enable natural ventilation. Eight fans improve the ventilation of the building in the summer.
Dairy production cowshed LC 440 for Holstein lactating cows is a new modern cowshed for loose housing of lactating cows. It is a semi-closed building with comfort cubicles covered by separated dried manure solids as bedding. The walls are made of woven fabric mesh with variable side curtains and a roof ridge slot for natural ventilation. If the air temperature is over 24 °C, the installed 24 axial fans switch automatically to improve ventilation.
The cowshed DC 23 for dry Holstein cows is a massive brick structure. It has an outdoor feeding passage and a rest area with loose housing on deep litter. The central slot of the roof ridge and the open windows allow ventilation. In summer, ventilation is improved by four axial fans.
Cowshed for maternity Holstein cows (MC 27) are used for housing 27 dairy cows before and at the time of calving. The maternity cowshed has free housing with straw bedding in nine maternity pens. Natural ventilation is provided by the ridge roof and mesh side walls.
Individual outdoor hutches, CaH 1, are used for Holstein calves in the first breeding period (2 months). It is made of white polyethylene. CaH has a length of 150 cm, a width of 112 cm, and a height of 135 cm. The floor is covered daily with straw bedding.
Barn for calves CaB 36 is a modern, spacious wooden building for housing 36 Jersey calves during the milk feeding period. Calves are in individual pens with straw bedding. The barn has sufficient natural ventilation thanks to the large open areas of the side walls, which are open in the summer and covered only with mesh.
Barn for Angus beef cattle BC 38 is a reconstructed brick cowshed (originally for dairy cows) used for beef cows with calves and beef cattle fattening (during the measurement of 38 animals) in group pens with littered lying areas. The natural ventilation of the barn is provided by partly open windows in the walls and a ridge roof slot.
2.2. Data Acquisition and Processing
Temperatures and relative humidity of the air were measured by instruments and sensors from the Ahlborn company (Ahlborn Mess- und Regelungstechnik GmbH, Eichenfeldstraße 1, 83607 Holzkirchen, Germany) outside and inside the buildings with registration at intervals of 1 min.
The Almemo 2690 with temperature and humidity sensors of the FHA 646 for outside measurement, together with the FY A600 sensor for CO2 measurement, was kept in a special weather station box.
The Almemo 2590-9 with sensors FHA 646 and FY A600 were used inside the barns near the animals. Temperature and humidity sensors of the FHA 646 type have a range of use from −20 to 80 °C and from 5 to 98% relative humidity. The measuring range of the capacitive sensor of relative humidity ranges from 0 to 100%, with an accuracy of ±2% in the range <90% relative humidity. The concentration of CO2 was measured by the Ahlborn sensors FY A600, with an operative range of 0 to 0.5% and an accuracy of ±0.01%.
The total dust mass concentration was measured by the special exact laser-photometer instrument Dust-Track™ II Aerosol Monitor 8530 produced by TSI in the USA, 500 Cardigan Road, Shoreview, MN 55126, with an operating range of 0.001 to 150 mg·m−3 and a resolution of ±0.1% of the reading of 0.001 mg·m−3, whichever is greater. Zero calibration was used before every use.
Size-selective impactors can be attached to the inlet of the Dust-Track™ II Aerosol Monitor 8530. Size-selective impactors are used to pre-condition the size range of the particles entering the instrument. PM1, PM2.5, PM4, and PM10 impactors were used to measure segregated mass fractions of airborne dust.
For the purpose of this measurement, 90 airborne dust concentration data points were collected for the total airborne dust concentration as well as for each PM size fraction of dust in each measured building. The measurement frequency was 2 s. Measurements were taken sequentially for each barn during warm summer days. The Dust-Track™ II device was always placed in a representative location of the investigated building at a height of 0.6 m above the floor.
The acquired datasets were processed using MS Excel, and some of the results (assessing whether differences between evaluated datasets are significant or not) were verified by the statistical software TIBCO SW Data Science Workbench Statistica Version 6 (ANOVA and Tukey’s HSD (Honestly Significant Difference) test). Data processed in the form of charts was processed in MS Excel.
3. Results
The average temperatures and relative humidity of the outdoor air at the time of airborne dust measurement are summarized in
Table 2. The average temperatures of the outdoor air ranged from 29.5 ± 0.2 °C to 36.0 ± 0.1 °C, and the average relative humidity ranged from 16.5 ± 0.2% to 40.3 ± 0.1%.
Table 2 also shows the corresponding temperatures, relative humidity, and CO
2 concentration of the indoor air in the buildings at the time of airborne dust measurement. Average indoor air temperatures ranged from 27.2 ± 0.2 °C to 43.3 ± 0.1 °C, and average relative humidity ranged from 15.4 ± 0.1% to 50.3 ± 2.9%.
The CO2i concentration inside the barns at the time of measurement in half of the buildings corresponded to the outdoor CO2e concentration, which was 400 ppm. In four buildings, the concentration of CO2i was slightly increased, ranging from 410 ± 0 ppm to 583 ± 171 ppm; in one barn, it was 939 ± 132 ppm.
The airborne dust measurement results are summarized in
Table 3. In addition to the total dust mass concentration (TDC), the concentrations of individual fractions PM
10, PM
4, PM
2.5, and PM
1 are also shown in
Table 3 for individual buildings.
The measured results of total dust mass concentration show significant differences between some buildings. Total dust mass concentration was the highest in cowshed LC 113 (108.09 ± 32.93 μg·m−3), an old cowshed with stanchion housing and straw bedding.
The use of plenty of bedded straw and limited ventilation was also manifested in the older brick barns DC 23 (86.81 ± 33.59 μg·m−3) and BC 38 (76.33 ± 17.72 μg·m−3). The difference in total dust mass concentration between them was not statistically significant.
Between cowshed LC 100 (60.22 ± 7.00 μg·m−3), calf hutch CaH 1 (58.63 ± 6.27 μg·m−3), cowshed LC 210 (58.2 ± 14.76 μg·m−3), cowshed LC 116 (57.29 ± 12.58 μg·m−3), cowshed LC 440 (53.62 ± 49.52 μg·m−3), and barn for calves CaB 36 (53.02 ± 4.82 μg·m−3), there was no statistically significant difference in total dust mass concentration. However, there are barns with and without straw bedding and significant differences in housing technology, as well as in terms of the concentration of housed animals inside buildings.
Total dust mass concentration was the lowest in maternity cowshed MC 27 (37.59 ± 13.74 μg·m−3) for housing cows before and after calving. A large amount of straw bedding is used in the pens, but the pens for the cows are spacious, and the natural ventilation through the mesh walls, supplemented by fans, has a very good effect on the cleanliness of the inside air.
There are also significant differences in the assessment of the PM10 dust fraction between some barns. The highest PM10 was in the barn for dry cows DC 23 (86.50 ± 23.70 μg·m−3); there was no significant difference between the barn for beef cattle BC 38 (73.99 ± 12.62 μg·m−3) and the cowshed LC 113 (69.80 ± 18.70 μg·m−3). A little lower PM10 was in cowshed LC 100 (58.04 ± 5.86 μg·m−3) and calf hutch CaH 1 (54.81 ± 5.18 μg·m−3), but there was no significant difference between calf hutch CaH 1 (54.81 ± 5.18 μg·m−3), cowshed LC 116 (52.67 ± 4.16 μg·m−3), and barn for calves CaB 36 (52.13 ± 3.39 μg·m−3).
Lower values of PM10 were measured in the cowshed without straw bedding LC 210 (46.51 ± 5.38 μg·m−3), the maternity cowshed MC 27 (30.86 ± 4.09 μg·m−3), and significantly lower compared to other barns in the large-capacity cowshed without straw bedding LC 440 (20.91 ± 5.24 μg·m−3).
In the assessment of PM4, the highest airborne dust level was in the cowshed, with the highest total dust mass concentration (with stanchion housing and straw bedding) of LC 113 (68.20 ± 18.41 μg·m−3). The lower fraction of PM4 was in the group of barns: cowshed LC 100 (55.01 ± 2.39 μg·m−3), barn for beef cattle BC 38 (52.42 ± 3.20 μg·m−3), barn for calves CaB 36 (49.11 ± 1.30 μg·m−3), and cowshed LC 116 (48.84 ± 1.61 μg·m−3). There was no statistically significant difference in PM4 between the calf hutch CaH 1 (48.09 ± 1.88 μg·m−3), the barn for dry cows DC 23 (47.90 ± 14.68 μg·m−3), and the cowshed LC 210 (44.27 ± 9.41 μg·m−3). Significantly lower PM4 was in maternity cowshed MC 27 (26.27 ± 1.84 μg·m−3) and the smallest PM4 was in large-capacity cowshed LC 440 without straw bedding (17.11 ± 3.23 μg·m−3).
In the evaluation of the dust fraction PM2.5, the worst situation was in cowshed LC 100 (53.53 ± 1.98 μg·m−3) and cowshed LC 113 (53.27 ± 14.73 μg·m−3). Lower PM2.5 was in the cowshed LC 116 (48.79 ± 2.39 μg·m−3) and barn for calves CaB 36 (47.56 ± 0.82 μg·m−3); there was no significant difference between the calf hutch CaH 1 (45.47 ± 1.13 μg·m−3) and barn for beef cattle BC 38 (44.56 ± 0.82 μg·m−3). There was no significant difference between the cowshed for lactating cows LC 210 (40.32 ± 1.81 μg·m−3) and the cowshed for dry cows DC 23 (40.09 ± 2.99 μg·m−3). A very low value of PM2.5 was in the maternity cowshed MC 27 (25.01 ± 1.18 μg·m−3), the significantly lowest of all buildings in the modern cowshed LC 440 (13.71 ± 0.92 μg·m−3).
The concentration of the smallest airborne dust particles, PM
1, was statistically very significantly different between almost all barns. The PM1 dust fraction was the highest in cowshed LC 100 (48.48 ± 1.18 μg·m
−3); it was slightly lower in barns: barn for calves CaB 36 (45.78 ± 1.17 μg·m
−3) and cowshed LC 116 (45.72 ± 0.84 μg·m
−3); there was no significant difference between them. The other barns differed statistically significantly from each other in terms of PM
1, as is clear from
Table 3. The lowest PM
1 fraction was the in large-capacity cowshed without straw bedding, LC 440 (12.69 ± 2.82 μg·m
−3).
In order to compare barns with and without straw bedding and to find out whether the use of straw has a significant effect on total dust mass concentration and how it affects individual fractions PM10, PM4, PM2.5, and PM1, sets of measured results of barns with straw bedding (LC 113, DC 23, BC 38, LC 100, CaH 1, LC 116, CaB 36, and MC 27) and without straw bedding (LC 210 and LC 440) were compared.
This comparison of the two sets shown in
Table 4 shows what the differences are and where the conditions are better from this point of view. In individual columns, the different superscript letters mean that there is a significant difference between the values in the column.
Table 5 shows the results of a statistical comparison of the average airborne dust levels (total dust mass concentration, PM
10, PM
4, PM
2.5, and PM
1) in solid brick constructions (masonry) with straw bedding, ventilated only by slightly open windows and doors (LC 113, DC 23, BC 38, and LC 116), with lightweight sheds also with straw bedding, the walls of which are only covered with nets (LC 100, CaB 36, and MC 27).
Table 6 shows the results of a statistical comparison of average dust levels in barns with natural ventilation supplemented for better ventilation with axial fans with a horizontal axis of rotation (DC 23, LC 210, LC 440, MC 27) and barns ventilated only by natural ventilation without fans (LC 113, BC 38, LC 100, CaH 1, LC 116, and CaB 36).
Table 7 shows the results of a statistical comparison of the average dust levels in cowsheds with separately housed cows (DC 23, LC 100, LC 210, LC 116, and LC 440), with barns only for calves (CaH 1 and CaB 36), and with barns in which cows are housed together with calves (LC 113, BC 38, and MC 27).
Figure 1 is a chart showing summary information on the total dust mass concentration of airborne dust. Each column shows 5 subcomponents of individual size groups of airborne dust particles in the range above 10 μm, from 4 μm to 10 μm, from 2.5 μm to 4 μm, from 1 μm to 2.5 μm, and smaller than 1 μm. The order of the columns in the picture corresponds to the order according to the average size of the total dust mass concentration in barns. The measured values of airborne dust particle fractions are given in mass concentration (μg·m
−3).
The share of individual fractions of airborne dust particles in the air in individual barns is rather variable. The share of the size distribution of airborne dust particle fractions PM ˂ 1 μm, 1 μm ≤ PM ˂ 2.5 μm, 2.5 μm ≤ PM ˂ 4 μm, 4 μm ≤ PM ˂ 10 μm, 10 μm ≤ PM as a percentage of total dust mass concentration in the examined barns is shown in
Table 8 and
Figure 2.
4. Discussion
Previous studies have reported higher airborne dust concentrations in poultry and pig barns compared to cattle barns [
4,
5,
6,
7,
8,
9,
10]. As a rule, however, more detailed attention was not paid to the differences in the method of housing, the construction, or the ventilation system of the barn. Under the conditions of this study, it is possible to look in more detail at the differences in the construction of the barns as well as the housing and ventilation solutions.
The results of extensive measurements [
42] in animal houses for poultry, pigs, cattle, and mink showed the lowest concentrations of airborne dust in cattle houses. According to the data in [
8], in the barns for cattle, the concentration of airborne dust PM
10 was 100 μg·m
−3, and PM
2.5 only 10 μg·m
−3. The results in
Table 3 show that in this research, PM
10 was lower than 100 μg·m
−3 in all barns, and PM
2.5 was always higher than 10 μg·m
−3.
The measurement method using the laser-photometer Dust-Track™ II Aerosol Monitor 8530 has the advantage of using impactors for detecting PM dust fractions, including the smallest particles, and is very suitable for comparative measurements between different objects [
42].
All measurements in this study were made in the same climatic area during the hot summer season (see
Table 2). However, certain differences in outdoor temperature and relative humidity are caused by air temperature fluctuations during the summer. It is practically impossible to achieve the same outdoor parameters for all measurements.
The internal temperatures and air humidity are also slightly different, which is also caused by the different massiveness of the structures, different thermal-technical properties of the investigated buildings, different methods of ventilation, different housing technologies, different excrement removal, etc.
The results in
Table 3 show significant differences between individual cattle barns in terms of the selected criteria for evaluating dust concentration. The division and evaluation of the researched barns into different groups (categories) according to several aspects (straw bedding vs. without straw bedding; massive structures vs. light uninsulated sheds; natural ventilation only vs. natural ventilation supplemented with fans) will help to reveal the reserves of the currently existing state and find possibilities for possible improvement of the current situation.
A comparison of the dust measurement results in
Table 4 shows that in all measured airborne dust parameters, i.e., total dust mass concentration, PM
10, PM
4, PM
2.5, and PM
1, the average concentration of dust particles in barns with straw bedding was statistically significantly higher than in barns without straw bedding.
The results in
Table 5 show that the total dust mass concentration and the concentration of PM
10, PM
4, and PM
2.5 dust particles were significantly higher in the massive constructions with window and door ventilation than in the light barns, where natural ventilation is easier thanks to the walls partially covered only by nets. There was an insignificant difference in the concentration of the smallest dust particles in PM
1.
The results in
Table 6 show that the total dust mass concentrations of PM
10, PM
4, PM
2.5, and PM
1 are significantly lower in barns equipped with fans for better ventilation in the summer than in barns that only have natural ventilation and are not equipped with fans. The effect of fans is statistically significant for reducing the total concentration of dust and all size fractions of dust.
The results in
Table 7 show that in barns with cows and calves housed together, total dust mass concentration was significantly higher (74.00 ± 36.88 μg·m
−3) than in cowsheds with cows housed separately (62.79 ± 30.74 μg·m
−3) and by separately housed calves (55.83 ± 6.26 μg·m
−3).
No statistically significant difference was found in the assessment of airborne dust concentration according to PM10 between the assessed groups of barns, but PM10 exceeded the limit of 50 μg·m−3 in all cases.
When evaluating PM4, the value was significantly lower in cowsheds with separately housed dairy cows (PM4 = 42.63 ± 15.47 μg·m−3) than in barns with calves (PM4 = 48.60 ± 1.70 μg·m−3) or in barns with cows housed together with calves (PM4 = 48.96 ± 20.41 μg·m−3), between which there was no significant difference.
Also, in the assessment of PM2.5, the value was lower in cowsheds with separately housed dairy cows (PM2.5 = 39.29 ± 13.94 μg·m−3), but it was not statistically significantly different from barns with cows and calves housed together (PM2.5 = 40.94 ± 14.63 μg·m−3), which was, however, significantly less than in barns with separate calves (PM2.5 = 46.51 ± 1.44 μg·m−3).
When evaluating the concentration of the smallest dust particles of PM1, there was a statistically significant difference between all evaluated groups of barns. The worst was PM1 in barns with calves (PM1 = 44.10 ± 1.98 μg·m−3), the lowest was in cowsheds with cows (PM1 = 34.05 ± 12.88 μg·m−3), and the lowest was PM1 in common barns with dairy cows and calves (PM1 = 31.63 ± 9.21 μg·m−3).
In all measured buildings, a large part (54.38 ± 20.82%) of the smallest PM1 dust particles were present in the air. This can be attributed to the fact that these smallest and lightest dust particles move freely in the flowing air, and their settling time is very long, so even a low airspeed keeps them in the air. Part of these small dust particles is removed by ventilation, and part is, on the other hand, swirled inside the space and lifted from the surfaces back into the air in the barn.
The percentage of the smallest PM
1 particles is significantly lower in barns equipped with fans than in barns ventilated only by natural ventilation, as can be seen from the statistical evaluation in
Table 6.
The smallest share of PM1 particles (24%) was in the large-capacity cowshed without straw bedding (LC 440). It is also the smallest in terms of absolute values (PM1 = 12.69 ± 2.82 μg·m−3). Conversely, the largest share (61%) of the largest dust particles above 10 μm was found in this cowshed, LC 440. This is mainly due to the higher airflow speed inside this cowshed. In addition to the natural flow through the mesh walls, 24 axial fans with a horizontal axis of rotation, which help to better ventilate the barn in the summer, are the source of higher flow speeds inside the barn. The PM1 particles are removed by air streams, and the largest particles above 10 μm recirculate inside the barn.
According to the authors [
19], organic dust consists mostly of particles with a diameter of less than 1 μm, which is unacceptable for long-term exposure and can be the cause of asthma, asthmatic syndromes, chronic bronchitis, and hypersensitivity pneumonitis (Farmer’s lung). According to the results in
Table 3 and
Table 8 and
Figure 1 and
Figure 2, it is clear that in this aspect our research and conclusions agree.
In the overall evaluation according to
Table 8, the largest particles, 10 μm ≤ PM, are the second fraction of dust particles in percentage order (15.94 ± 18.29%).
The third size fraction of dust particles (4 μm ≤ PM < 10 μm) accounted for 13.70 ± 12.78% of the total dust concentrations in the barns.
The fourth group of dust particles consists of the size fraction 1 μm ≤ PM < 2.5 μm, which had a share of 9.07 ± 4.25%.
The smallest part of the total concentration of dust in the investigated stables was made up of particles 2.5 μm ≤ PM ˂ 4 μm, which were 6.91 ± 3.94%.
The authors [
9] report that the average PM
10 in dairy cattle farms (cubicle housing without straw bedding) was 40 μg·m
−3, ranging from 14 to 95 μg·m
−3, and the average PM
2.5 was 13.8 μg·m
−3, ranging from 3.9 up to 24.9 μg·m
−3. The results of PM
10 measured in cowsheds without litter (33.71 ± 13.86 μg·m
−3), see
Table 3, correspond approximately to these average values; the results of PM
10 found in barns with straw bedding (60.11 ± 19.93 μg·m
−3) correspond to the upper half of the range according to [
9]. PM
2.5 values found in cowsheds without straw bedding (27.02 ± 13.38 μg·m
−3) exceed the data according to [
9]. They are even more significantly exceeded by the results from barns with straw bedding (44.78 ± 10.18 μg·m
−3); see
Table 4.
The authors of the research [
19] on small dairy farms state that the measured values of PM
10 during the distribution of hay and feed flour did not exceed the limit of 5 mg·m
−3 for organic dust, but in some individual cases, they exceeded the value of 10 mg·m
−3. The stated values are thus significantly higher than the results found by this research, presented in
Table 3 and others.
Research results in Finnish cubicle cow houses [
41] indicate mean concentrations of total airborne dust of 0.2–1.9 μg·m
−3, which is significantly more than the results of the measurements of this research in the summer period, presented in
Table 3. Measurements [
41] were made during winter and early autumn, when the indoor temperatures and relative humidity varied from 7 to 17 °C (mean 12.7 °C) and 55 to 95% (mean 87%), respectively. The outdoor temperature ranged from +2 to −20 °C. The external and internal conditions differ considerably from those of this research (see
Table 2). Due to the cold measurement conditions, the CO
2 concentration results were also higher in the Finnish stables than in the investigated barns of this case study in the Czech Republic in the summer.
Concentrations of airborne particulate matter, ammonia, and carbon dioxide in large-scale uninsulated loose-housing cowsheds in Estonia were measured from September 2008 to August 2009 [
43]. The mean recorded concentrations of PM
total were 205 ± 270 μg·m
−3, PM
10 65 ± 121 μg·m
−3, PM
2.5 18 ± 46 μg·m
−3, and PM
1.0 10 ± 11 μg·m
−3. The overall mean inside air CO
2 concentration was 553 ± 315 ppm. The mean air temperature was 9.6 ± 6.6 °C, and the relative humidity was 83.2 ± 16.8%.
The results of measuring total mass dust concentration TDC from 37.59 ± 13.74 μg·m
−3 to 108.09 ± 32.93 μg·m
−3 achieved in this research (
Table 3) are higher in [
43] (TDC corresponds to PM
total). Also, the PM
10 values in this research, from 30.86 ± 4.09 μg·m
−3 to 69.80 ± 18.70 μg·m
−3 are lower than in [
43]. On the contrary, the average values found during this research (
Table 3) for PM
2.5 from 25.01 ± 1.18 μg·m
−3 to 53.27 ± 14.73 μg·m
−3 and PM
1 from 19.50 ± 0.82 μg·m
−3 to 38.46 ± 5.55 μg·m
−3 are higher than in [
43].
The low mean air temperatures and high relative air humidity measured in [
43] correspond to the colder climatic regions of Estonia; however, this comparison is interesting for the mutual comparison of airborne dust concentration and airborne dust individual fractions. It can be assumed that the high concentrations of PM
2.5 and PM
1 fractions achieved in this research (
Table 3) are caused by high temperatures and low relative air humidity when measured in the summer period in the Czech Republic.
If it is an assessment of the cleanliness of the air in the barn from the point of view of occupational health [
35], the occupational exposure limits important for animal houses, which are for feather (4 mg·m
−3), wool, fur, and other animal dust (6 mg·m
−3), straw, and cereals (6 mg·m
−3), were not exceeded in any measurement, even in the case of total dust mass concentration results.
Considering the current trend in livestock breeding to strive for the most favorable animal welfare, which will be close to the natural conditions of animals kept in the wild, it is interesting to compare the internal environmental conditions in the barns in terms of air pollution by airborne dust with the limits recommended for the stay of people in the outdoor environment. However, these data are also interesting from the point of view of the stay of people in the relevant premises as part of their work activities and duties.
When comparing the measured values with the limit value of recommended air quality standards for PM
10 = 50 μg·m
−3 for the outdoor environment for a 24 h exposure period [
31,
32,
33,
34,
35], the lower value was only in cowshed without straw bedding LC 210 (46.51 ± 5.38 μg·m
−3) and maternity cowshed MC 27 (30.86 ± 4.09 μg·m
−3), and significantly lower compared to other barns was in large-capacity cowshed without straw bedding LC 440 (20.91 ± 5.24 μg·m
−3). This cowshed was the only one of the investigated barns that would also meet the requirement of PM
10 = 25 μg·m
−3 for an annual exposure period. The requirement for an annual exposure period [
37] of PM
10 = 40 μg·m
−3 would also be met for cowshed MC 27.
The recommended air quality standards are slightly different. According to [
37] PM
2.5 = 20 μg·m
−3 for an annual exposure period, according to [
38] PM
2.5 = 8 μg·m
−3 for an annual exposure period, and PM
2.5 = 25 μg·m
−3 for a 24-h exposure period. The PM
2.5 value = 8 μg·m
−3 for an annual exposure period was exceeded in all barns. The value of PM
2.5 = 20 μg·m
−3 was not exceeded only in cowshed LC 440 (PM
2.5 = 13.71 ± 0.92 μg·m
−3), and the limit value of PM
2.5 = 25 μg·m
−3 was reached by the maternity cowshed MC 27 (25.01 ± 1.18) μg·m
−3.