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Article

CO2 Concentration and Occupants’ Symptoms in Naturally Ventilated Schools in Mediterranean Climate

by
Jesica Fernández-Agüera
*,
Miguel Ángel Campano
*,
Samuel Domínguez-Amarillo
*,
Ignacio Acosta
and
Juan José Sendra
Instituto Universitario de Arquitectura y Ciencias de la Construcción, Escuela Técnica Superior de Arquitectura, 41007 Seville, Spain
*
Authors to whom correspondence should be addressed.
Buildings 2019, 9(9), 197; https://doi.org/10.3390/buildings9090197
Submission received: 8 July 2019 / Revised: 21 August 2019 / Accepted: 27 August 2019 / Published: 29 August 2019

Abstract

:
A large part of the school building stock in Andalusia lacks ventilation facilities, so that the air renewal of the classrooms is achieved through the building envelope (air infiltration) or the opening of windows. This research analyses the airtightness of the classrooms in Andalusia and the evolution of CO2 concentration during school hours through in situ monitoring. Pressurization and depressurization tests were performed in 42 classrooms and CO2 concentration was measured in two different periods, winter and midseason, to study the impact of the different levels of aperture of windows. About 917 students (11–17 years of age) were surveyed on symptoms and effects on their health. The mean n50 values are about 7 h−1, whereas the average CO2 concentration values are about 1878 ppm, with 42% of the case studies displaying concentrations above 2000 ppm with windows closed.

1. Introduction

When the environmental performance of building envelopes is analysed, ventilation is identified as one of the main variables affecting energy demand, the degree of environmental comfort (ISO 7730: 2005; UNE-CR 1752: 2008) [1,2], the accumulation rate of CO2, suspended particles and pollutants (EN 15251: 2007) [3], and respiratory health in prolonged periods of exposure [4].
In non-residential buildings, European ventilation standards (EN 13779: 2008) [5] establish the need to guarantee a minimum outdoor airflow to ensure adequate Indoor Air Quality (IAQ) control, making it necessary to resort to mechanical ventilation with stages of infiltration. In Spain, it was only in 2007 that the regulations established that the ventilation of the school buildings had to be mechanical in order to ensure an adequate IAQ (Indoor Air Quality) [6]. Consequently, approximately 8000 schools in the school building stock of the Mediterranean area do not meet this requirement [7]. Adapting these buildings would entail major investment, maintenance and energy consumption. For this reason, several public bodies in Spain are promoting natural ventilation as a system for the control of IAQ, contrary to what is established in these regulations.
In Spain, where education is obligatory until the age of 16, students spend an average of six hours a day in these buildings, not counting the hours of extracurricular activities, from Monday to Friday during approximately nine months a year (winter and mid-seasons).
For this reason, the control of the IAQ and energy consumption associated with different ventilation strategies has been studied in various climatic zones. Studies on IAQ control have been carried out in cold [8,9,10,11], mild [12] and warm climates [13]. Given the similarities in the climate it is worth noting research in Portugal which examines the relationship between indoor air quality and outdoor pollutants in classrooms with mechanical ventilation systems [14]. In many cases, there is evidence of poor indoor air quality in schools, with negative effects on the health of their occupants, potentially leading to allergic diseases or asthma [15]. In terms of the energy consumption associated with ventilation systems [16,17,18,19], a study analysing different ventilation systems and their associated energy consumption in Italy is a notable example in the Mediterranean area.
The main objective of this study is to characterize the indoor environment of the classrooms and the airtightness of the envelope to establish whether the parameters obtained are adequate for learning.

2. Materials and Methods

To develop this study, the following phases were established:
  • Sample
  • On-site measurement
  • Survey design
  • Airtightness

2.1. Sample

One to three school buildings were chosen in the most representative climatic areas in Andalusia (zones A4, B4, C3 and C4), following the Spanish energy performance zoning and the studies by De La Flor et al. [20,21,22]. These areas are classed as Hot-summer Mediterranean climate (Köppen CSa) and Cold Semi-arid climate (Köppen BSk) and include cold to temperate areas in winter (types C, B, or A), as well as warm or average summers (4 or 3). 3 to 10 classrooms were chosen in each of the schools, depending on availability. A total of 42 classrooms from 8 school buildings were sampled (Table 1).
All classrooms in Andalusia are standardized and follow the design standards established for non-university educational institutions (ISE 2003) [24]. Classrooms are approximately 50 m2 and 3 metres high, with a maximum capacity of 30 students. The windows tend to be found to the left and the distribution of the furniture and entrance doors is as shown in Figure 1. None of the measured classrooms have suspended ceilings or perforations in the inner partitions with adjacent classrooms. The external vertical wall is usually composed of a half-brick wall (with or without rendering), air chamber, thermal insulation (projected polyurethane) and a simple hollow brick wall with plaster setting. The internal partitions in particular are composed of a half-brick wall with plaster on either side.
In existing school buildings, a measurement campaign was carried out and a data collection protocol applied to the classrooms selected [25], covering the following aspects:
  • Name and type of school building to which the classroom belongs.
  • Location, orientation and climatic zone.
  • Characteristics of the classroom and the furniture distribution.
  • Location and operation of existing HVAC (Heating, Ventilation and Air Conditioning) systems.
  • Window dimensions, composition and opening.

2.2. On-site Measurements

Measurement of indoor air quality (temperature, relative humidity and CO2 concentration) was developed during the normal operation of teaching activities for a period of 45 min per measurement. A dot matrix was established for measurements and a Testo 435-2 data logger with temperature, relative humidity and CO2 sensors was used. The sensors have an accuracy of 0.3 °C for temperature; 2% for relative humidity; and ± 50 ppm for CO2 concentration. The measuring points respond to a matrix of 3 × 2 locations at 2 different heights (0.60 and 1.70 m) (Figure 2) [25,26].
For the analysis of the results, a distinction was made between case studies measured under operational conditions with open windows and those with closed windows.
The measurements were subject to a series of limitations imposed by the sample, including classroom typology climate zones defined in southern Spain and net floor areas < 105 m2 and window areas < 17 m2 [27].

2.3. Survey Design

The purpose of the survey was to use a systematic approach to gather information from students and to discretize the findings in order to examine various symptoms and health effects in students. This process took approximately 20 min per classroom. Surveys were collected throughout an entire year in the last 20 min of one subject.
The survey content included questions that covered occupant and building information:
  • The respondent’s age and sex.
  • The occupant’s position in the classroom.
  • Various symptoms and health effects (Figure 3). The scale for the analysis varies from a score of 0 when they report never suffering from a certain symptom to 1 when reporting it daily.

2.4. Airtightness

The airtight tests were carried out following the protocol established by UNE EN 13829:2002 and using the Minneapolis Blower Door Model4/230 V System. Since the classroom has two access doors, the specific protocols developed below were followed to establish the actual airtightness of the classroom through its envelope (Figure 4):
  • Protocol 1 (P1): Blower door was installed in door A. Door B was not sealed (free air passes through its gaps). V50,P1 was obtained
  • Protocol 2 (P2): Blower door was installed in door B. Door A was not sealed (free air passes through its gaps). V50,P2 was obtained
  • Protocol 3 (P3): Blower door was installed in door B. Door A was sealed. V50,P3 was obtained
Equations (1) to (5), deduced from the BS 5925 standard using a simplification of the “crack flow equation” [28], provide the infiltration values measured in each of these three ± 50 Pa sample hypotheses established for each classroom.
n 50 , P 1 = V 50 , D o o r A + V 50 , e n v V
n 50 , P 2 = V 50 , D o o r B + V 50 , e n v V
n 50 , P 3 = V 50 , e n v V
n 50 , t = V 50 , D o o r A + V 50 , D o o r B + V 50 , e n v V
n 50 , t = n 50 , P 1 + n 50 , P 2 n 50 , P 3
where:
  • V50,DoorA is the air leakage rate at 50 Pa which circulates through door A, in m3/h;
  • V50,DoorB is the air leakage rate at 50 Pa which circulates through door B, in m3/h;
  • V50,env is the air leakage rate at 50 Pa which circulates through the envelope, in m3/h;
  • V is the internal volume of the room, in m3;
  • n50,P1 is the infiltration rate at 50 Pa in protocol 1, in h−1;
  • n50,P2 is the infiltration rate at 50 Pa in protocol 2, in h−1;
  • n50,P3 is the infiltration rate at 50 Pa in protocol 3, in h−1;
  • n50,t is the infiltration rate at 50 Pa through the envelope and doors of the room, in h−1.

3. Results

3.1. Indoor Air Quality

During the measurement period, 28 case studies had the windows closed (67%); 23 of these were measured in the winter season. Of these 28 case studies, 65% had the heating system working. The measured interior temperature oscillated between 17.8 °C and 22.7 °C in the winter season, the lowest temperature was obtained for a case study with no heating system in the warmer climate zone. Relative humidity ranged from 40.6% to 64.3% (Table 2).
14 of the 42 case studies (33%) had the windows open. Of these, eight cases had windows open in winter, which indicates that the heating systems were not well regulated and the heat had to be dissipated in cases where the interior temperature was higher, or that the students perceived the stale air of the environment prompting a need to ventilate the room, despite the resulting energy loss. The interior temperature ranged from 18.4 °C to 25.6 °C and the relative humidity from 31.2% to 60% (Table 3).
Concentrations of CO2 fluctuated widely over time in all cases, oscillating between a minimum of 625 ppm and a maximum of 3357 ppm (Figure 5).
The CO2 concentration measured usually exceeds WHO recommendations (which set a limit value of 1000 ppm for healthy environments) [29] pointing to low refurbishment rates and the potential risk of air-quality associated problems. This aspect is highly important when windows are closed, with 89.3% above the threshold. Average values below 1600 ppm were only recorded in 39% of classrooms, with 43 % of classrooms displaying concentrations above 2000 ppm.
When the windows were open, CO2 concentration fell below 1000 ppm in 28% of case studies. As expected, values above 2000 ppm were not recorded when the windows were open, although values between 1600 and 2000 ppm were recorded in two case studies.

3.2. Health symptoms

The symptoms that most students report according to the surveys are dizziness, dry skin, headache and tiredness, both with windows closed (Table 4) and with windows open (Table 5). These conditions have been expressed in almost all case studies in climatic zones C3 and C4, in some in B4. They are also reported in some case studies in A4, albeit with lower values.
The symptom which has been reported least frequently in the classroom is eye irritation. 42% of the case studies with the closed windows do not report any symptoms, while only 14% report no symptoms of any sort in the case studies with open windows.

3.3. Airtightness

The values of n50 range from 2.6 h−1 (minimum) to 10 h−1 (maximum), both recorded in the B4 climate zone with the highest number of samples. The average value of n50 is 6.97 h−1, with a standard deviation of 2.06 h−1; and models with the lowest n50 values are those in the C3 climate zone, where the lowest average temperature values are recorded in the winter. The highest values are in zone B4, where great attention has been paid to the construction of the envelopes, despite the fact that these areas with no coast and lower wind speeds are not necessarily warmer (Figure 6 and Table 6).

4. Discussion

The measurements were subject to a series of limitations imposed by the sample: classroom typology, climate zones defined in southern Spain, and occupants aged between 11 and 17.
The coefficients of linear correlation between n50 and the different environmental parameters, exterior and interior temperatures, interior wind speed and CO2 concentration, are quite low, especially in cases where the windows are open and used as a control group. The correlation with CO2 concentration is almost negligible, indicating that other factors such as time previously spent in the classroom, the time of measurement, or if the window or door has been opened prior to the measurement, are more important in the airtightness of the enclosure (Table 7).
In all cases, the correlation coefficients between the CO2 concentration and the different symptoms shown by the students during the measurement period are positive, although R2 values are very low, ranging from 0.12 to 0.30 for the case with windows closed and almost zero values with the windows open.
When the windows were closed, the symptoms of itchiness and nasal congestion were reported in over 30% of the cases in correlation with the CO2 concentration, with correlation coefficients of 0.554 and 0.441, respectively. Other factors with a high correlation coefficient are chest oppression and nausea (Figure 7).
In the case studies where the windows are open, the symptom showing the highest correlation is itchiness with a value of 0.369, although this only accounts for 14% of the cases (Table 8).
In Figure 7, the different case studies have been represented in a scatter plot. The symptomatology shown by the students in the case studies with open windows (triangles) displays higher values than those found in the case studies with closed windows and higher concentrations of CO2. In the case of closed windows, a higher frequency of symptomatology is observed by students in higher indoor CO2 concentrations. When the windows are open almost all the subjects of the sample report dry skin and headaches, whereas with the windows closed, dizziness accounts for the highest values.

5. Conclusions

In the wide study sample of classrooms with no mechanical ventilation system in middle schools in the Mediterranean area, no direct relationship has been identified between the airtightness of the envelope and the internal concentration of CO2. This indicates that there is a significant influence from other factors affecting the quality of the indoor environment, including class schedules and the opening and closing of windows and doors. In addition, the measured CO2 concentration exceeded the WHO recommendations (a 1000 ppm threshold is set for healthy environments) even when the windows were open, with CO2 concentration falling below 1000 ppm in only 28% of case studies with open windows and in 17% of the total case studies. This consequence is especially interesting, as the role of the envelope as a predictor of indoor air-quality behaviour is reduced and the need for mechanical ventilation is emphasized, something which must be taken into account in the generation of models of this type of building.
As expected, CO2 levels were higher in closed classrooms than in those ventilated by opening windows. However, cases were identified in which—in response to the air quality perceived—users were willing to sacrifice thermal comfort in winter in exchange for better ventilation. In some classrooms windows were opened to control the interior atmosphere causing interior temperatures to fall below 20 °C with the heating system in operation. In addition to the effect that this has on indoor air-quality conditions in the classroom, the impact on energy consumption is an important factor to be taken into consideration.
One of the main findings of this work is that, as noted, there was a higher level of symptomatology, or level of discomfort perceived by the occupants, when the windows were open. In 42% of the case studies with closed windows no symptomatology of any sort is reported, despite the presence of objective indicators of poorer quality of the internal atmosphere. In contrast, with open windows, only 14% of the case studies do not report symptoms in their responses. This indicates the presence of degradation factors of environmental quality, such as external contamination and the presence of biological or chemical aerosols, which are not being measured or incorporated into the analysis. Other factors include changes in personal perception associated with the room in free evolution, compared to rooms with controlled conditions, or rooms at least decoupled from the external environment. This opens a future pathway of discussion over the dilemma for better ventilation strategies and the problem of the urban actual degradation. Despite the usual assumptions, in this large study sample there is a greater symptomatology experienced with open windows, while 72% of the measured values of CO2 concentration levels were above 1000 ppm in these classrooms.
As a counterpoint, certain symptoms, such as itchiness and nasal congestion can be identified in periods when the windows are closed, since they appear when the CO2 level rises. In the case studies with windows closed, the average CO2 concentration was 1878 ppm, with the symptom onset level appearing at around 1400 ppm.
The findings of this study further highlight the need for adequate controlled ventilation systems, as the relatively low CO2 levels when operating under natural ventilation conditions (but in general above 1000 ppm) do not reflect the real air-quality problems and cannot ensure an adequate thermal environment is maintained.
It also seems appropriate to complement the role of CO2 as a standalone reference indicator of indoor air quality in schools. Findings show the need for further studies that include other complementary indicators associated with the operating regime and pollutants found in the air to assure a correct interpretation of data. It can be established that, although the values of CO2 concentration are lower when the windows are open, this is not guaranteeing a complete acceptance by the occupants, given that there is an additional set of conditions related to other environmental parameters of the exterior that cannot be identified exclusively with this single CO2 control parameter.

Author Contributions

Conceptualization, J.F.-A., M.Á.C., S.D.-A. and J.J.S.; Data curation, J.F.-A., M.Á.C. and I.A.; Formal analysis, J.F.-A., M.Á.C. and S.D.-A.; Funding acquisition, J.F.-A., M.Á.C., S.D.-A. and J.J.S.; Investigation, J.F.-A., M.Á.C., S.D.-A. and I.A.; Methodology, J.F.-A., M.Á.C., S.D.-A. and J.J.S.; Project administration, J.F.-A., M.Á.C. and J.J.S.; Supervision, J.F.-A., M.Á.C., S.D.-A. and J.J.S.; Validation, J.F.-A., M.Á.C. and S.D.-A.; Writing–original draft, J.F.-A. and M.Á.C.; Writing – review & editing, J.F.-A., M.Á.C., S.D.-A., I.A. and J.J.S.

Funding

This research was partially funded by the PIF Program of the Universidad de Sevilla (V Plan Propio).

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. ISO. Ergonomics of the Thermal Environment—Analytical Determination and Interpretation of Thermal Comfort Using Calculation of the PMV and PPD Indices and Local Thermal Comfort Criteria; ISO 7730:2005; International Organization for Standardization: Geneva, Switzerland, 2005. [Google Scholar]
  2. CEN-European Committee for Standardization. Ventilation for Buildings. Design Criteria for the Indoor Environment; CR 1752:1998; European Committee for Standardization: Brussels, Belgium, 2008. [Google Scholar]
  3. AENOR-Asociación Española de Normalización y Certificación. Indoor Environmental Input Parameters for Design and Assessment of Energy Performance of Buildings Addressing Indoor Air Quality, Thermal Environment, Lighting and Acoustics; UNE-EN 15251; AENOR-Asociación Española de Normalización y Certificación: Madrid, Spain, 2008. [Google Scholar]
  4. Fisk, W.J. How home ventilation rates affect health: A literature review. Indoor Air 2018, 28, 473–487. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  5. CEN-European Committee for Standardization. Ventilation for Non-Residential Buildings-Performance Requirements for Ventilation and Room-Conditioning Systems; EN 13779: 2008; CEN-European Committee for Standardization: Brussels, Belgium, 2008. [Google Scholar]
  6. Gobierno de España. Real Decreto 1826/2009, de 11 de Diciembre, por el que se Modifica el Reglamento de Instalaciones Térmicas en los Edificios, Aprobado por el Real Decreto 1027/2007; Boletín Of. del Estado: Madrid, España, 2009; Volume 298, pp. 104924–104927. [Google Scholar]
  7. ZEMeds. Promoting Renovation of Schools in a Mediterranean Climate up to Nearly Zero-Energy Buildings. 2016. Available online: http://www.zemeds.eu/ (accessed on 5 February 2019).
  8. Karimipanah, T.; Awbi, H.B.; Sandberg, M.; Blomqvist, C. Investigation of air quality, comfort parameters and effectiveness for two floor-level air supply systems in classrooms. Build. Environ. 2007, 42, 647–655. [Google Scholar] [CrossRef]
  9. Shendell, D.G.; Prill, R.; Fisk, W.J.; Apte, M.G.; Blake, D.; Faulkner, D. Associations between classroom CO2 concentrations and student attendance in Washington and Idaho. Indoor Air 2004, 14, 333–341. [Google Scholar] [CrossRef] [PubMed]
  10. Mainka, A.; Zajusz-Zubek, E.; Mainka, A.; Zajusz-Zubek, E. Indoor Air Quality in Urban and Rural Preschools in Upper Silesia, Poland: Particulate Matter and Carbon Dioxide. Int. J. Environ. Res. Public Health 2015, 12, 7697–7711. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  11. Hedge, A. Ergonomic Workplace Design for Health, Wellness, and Productivity; CRC Press: Boca Raton, FL, USA, 2016. [Google Scholar]
  12. Almeida, S.M.; Canha, N.; Silva, A.; do Carmo Freitas, M.; Pegas, P.; Alves, C.; Pio, C. A Children exposure to atmospheric particles in indoor of Lisbon primary schools. Atmos. Environ. 2011, 45, 7594–7599. [Google Scholar] [CrossRef]
  13. Kalimeri, K.K.; Saraga, D.E.; Lazaridis, V.D.; Legkas, N.A.; Missia, D.A.; Tolis, E.I.; Bartzis, J.G. Indoor air quality investigation of the school environment and estimated health risks: Two-season measurements in primary schools in Kozani, Greece. Atmos. Pollut. Res. 2016, 7, 1128–1142. [Google Scholar] [CrossRef]
  14. Almeida, R.M.; de Freitas, V.P. IEQ Assessment of Classrooms with an Optimized Demand Controlled Ventilation System. Energy Procedia 2015, 78, 3132–3137. [Google Scholar] [CrossRef] [Green Version]
  15. Chithra, V.S.; SM, S.N. A review of scientific evidence on indoor air of school building: Pollutants, sources, health effects and management. Asian J. Atmos. Environ. 2018, 12, 87–108. [Google Scholar] [CrossRef]
  16. Wachenfeldt, B.J.; Mysen, M.; Schild, P.G. Air flow rates and energy saving potential in schools with demand-controlled displacement ventilation. Energy Build. 2007, 39, 1073–1079. [Google Scholar] [CrossRef]
  17. Ferdyn-Grygierek, J.; Bartosz, D.; Specjał, A.; Grygierek, K. Analysis of Accuracy Determination of the Seasonal Heat Demand in Buildings Based on Short Measurement Periods. Energies 2018, 11, 2734. [Google Scholar] [CrossRef]
  18. Griffiths, M.; Eftekhari, M. Control of CO2 in a naturally ventilated classroom. Energy Build. 2008, 40, 556–560. [Google Scholar] [CrossRef]
  19. Stabile, L.; Massimo, A.; Canale, L.; Russi, A.; Andrade, A.; Dell’Isola, M. The effect of ventilation strategies on indoor air quality and energy consumptions in classrooms. Buildings 2019, 9, 110. [Google Scholar] [CrossRef]
  20. Ministerio de Fomento del Gobierno de España. Código Técnico de la Edificación. 2006. Available online: http://www.codigotecnico.org (accessed on 20 April 2019).
  21. Consejería de Innovación de la Junta de Andalucía. Orden VIV/1744/2008 de 9 de junio, por la que se aprueba la ‘Zonificación Climática de Andalucía por Municipios para su uso en el Código Técnico de la Edificación en su sección de Ahorro de Energía apartado de Limitación de Demanda Energética (CTE-HE1). Boletín Of. Junta Andal. 2008, 254, 4216. [Google Scholar]
  22. De la Flor, F.J.S.; Domínguez, S.Á.; Félix, J.L.M.; Falcón, R.G. Climatic zoning and its application to Spanish building energy performance regulations. Energy Build. 2008, 40, 1984–1990. [Google Scholar] [CrossRef]
  23. Kottek, M.; Grieser, J.; Beck, C.; Rudolf, B.; Rubel, F. World Map of the Köppen-Geiger climate classification updated. Meteorol. Z. 2006, 15, 259–263. [Google Scholar] [CrossRef]
  24. Junta de Andalucía. Orden de 24 de enero de 2003 de la Consejería de Educación y Ciencia de la Junta de Andalucía por la que se aprueban las ‘Normas de diseño y constructivas para los edificios de uso docente. Boletín Of. Junta Andal. 2003, 43, 4669. [Google Scholar]
  25. Campano, M.Á.; Domínguez-Amarillo, S.; Fernández-Agüera, J.; Sendra, J.J. Thermal Perception in Mild Climate: Adaptive Thermal Models for Schools. Sustainability 2019, 11, 3948. [Google Scholar] [CrossRef]
  26. Campano, M.A.; Sendra, J.J.; Domínguez, S. Analysis of thermal emissions from radiators in classrooms in Mediterranean climates. Procedia Eng. 2011, 21, 106–113. [Google Scholar] [CrossRef]
  27. Campano, M.A. Confort térmico y eficiencia energética en espacios con alta carga interna climatizados: Aplicación a espacios docentes no universitarios en Andalucía. Ph.D. Thesis, University of Seville, Sevilla, Spain, 2015. [Google Scholar]
  28. British Standards. Code of Practice for Ventilation Principles and Designing for Natural Ventilation; BS 5925:1991; British Standards Institution: London, UK, 1991. [Google Scholar]
  29. Penney, D.; Benignus, V.; Kephalopoulos, S.; Kotzias, D.; Kleinman, M.; Verrier, A. Guidelines for Indoor Air Quality; World Health Organization Regional Office for Europe: Copenhagen, Denmark, 2010. [Google Scholar]
Figure 1. Classroom prototype following design standards for regional educational institutions.
Figure 1. Classroom prototype following design standards for regional educational institutions.
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Figure 2. Measuring matrix in the classrooms.
Figure 2. Measuring matrix in the classrooms.
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Figure 3. Extract from student survey.
Figure 3. Extract from student survey.
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Figure 4. Protocols of Blower Door test.
Figure 4. Protocols of Blower Door test.
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Figure 5. Accumulated frequency and percentage of measured CO2 concentration in classrooms with closed windows (a) and open windows (b).
Figure 5. Accumulated frequency and percentage of measured CO2 concentration in classrooms with closed windows (a) and open windows (b).
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Figure 6. n50 measured frequency.
Figure 6. n50 measured frequency.
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Figure 7. Scatter plot showing CO2 concentration and student symptomatology.
Figure 7. Scatter plot showing CO2 concentration and student symptomatology.
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Table 1. Sample by climate zone.
Table 1. Sample by climate zone.
Climate ZoneLocationSchoolNo. of ClassroomsNo. of Occupants
Spanish Building CodeKöppen Climate Scale [23]
A4BSkAlmeríaS 1496
CsaHuelvaS 2254
B4CsaSevillaS 38167
CsaSevillaS 49158
C3CsaGranadaS 5249
CsaGranadaS 612287
CsaGranadaS 7360
C4CsaJaénS 8246
TOTAL42
Table 2. Average values of indoor environment parameters with closed windows during the measurement period (45 min per case). Where: “Heating” is the heating system operation (On = 1; Off = 0); “Occupants” is the number of occupants (No.); “ T o ¯ ” is the mean outdoor temperature (°C); “ T a ¯ ” is the mean indoor air temperature (°C); “ R H ¯ ” is the relative humidity (°C); “ C O 2   c o n c ¯ ” is the mean indoor CO2 concentration (ppm).
Table 2. Average values of indoor environment parameters with closed windows during the measurement period (45 min per case). Where: “Heating” is the heating system operation (On = 1; Off = 0); “Occupants” is the number of occupants (No.); “ T o ¯ ” is the mean outdoor temperature (°C); “ T a ¯ ” is the mean indoor air temperature (°C); “ R H ¯ ” is the relative humidity (°C); “ C O 2   c o n c ¯ ” is the mean indoor CO2 concentration (ppm).
Case StudyClimate ZoneSeasonStart TimeHeating
(On = 1; Off = 0)
Occupants
(No.)
T o ¯
(°C)
T a ¯
(°C)
R H ¯
(%)
C O 2   c o n c ¯
(ppm)
1A4Midseasons12:1502315.421.540.6992
2A4Midseasons10:450258.419.141.41995
3A4Midseasons13:1502515.417.848.1852
4B4Winter8:451304.319.252.71875
5B4Winter10:4512110.621.652.32265
6B4Winter12:1512214.922.255.81876
7B4Winter9:4512110.619.347.31194
8B4Winter13:1501914.921.044.51124
9B4Winter10:4512010.619.849.61505
10B4Winter13:1511414.921.046.21253
11B4Winter13:1512514.921.152.31540
12B4Midseasons9:4501916.720.559.1591
13B4Winter9:451256.421.454.32044
14B4Winter8:451206.419.758.32055
15B4Winter12:1501010.420.464.33337
16C3Winter10:451244.320.151.51650
17C3Winter13:1502514.920.158.22087
18C3Midseasons13:1502922.124.237.31290
19C3Winter10:451188.922.741.01541
20C3Winter8:451306.319.559.12064
21C3Winter12:1501813.819.649.51442
22C3Winter9:451264.321.555.31963
23C3Winter13:1502814.922.650.02043
24C3Winter12:1512715.021.947.52457
25C3Winter12:1511815.021.245.92877
26C3Winter12:1511515.021.947.42433
27C4Winter9:451234.322.744.42832
28C4Winter12:1512316.721.355.83392
Table 3. Average values of indoor environment parameters with open windows during the measurement period (45 min per case). Where: “Heating” is the heating system operation (On = 1; Off = 0); “Occupants” is the number of occupants (No.); “ T o ¯ ” is the mean outdoor temperature (°C); “ T a ¯ ” is the mean indoor air temperature (°C); “ R H ¯ ” is the relative humidity (°C); “ C O 2   c o n c ¯ ” is the mean indoor CO2 concentration (ppm).
Table 3. Average values of indoor environment parameters with open windows during the measurement period (45 min per case). Where: “Heating” is the heating system operation (On = 1; Off = 0); “Occupants” is the number of occupants (No.); “ T o ¯ ” is the mean outdoor temperature (°C); “ T a ¯ ” is the mean indoor air temperature (°C); “ R H ¯ ” is the relative humidity (°C); “ C O 2   c o n c ¯ ” is the mean indoor CO2 concentration (ppm).
Case StudyClimate ZoneSeasonStart TimeHeating
(On = 1; Off = 0)
Occupants
(No.)
T o ¯
(°C)
T a ¯
(°C)
R H ¯
(%)
C O 2   c o n c ¯
(ppm)
29A4Midseasons10:250238.420.933.41337
30B4Winter12:3502413.122.548.71499
31B4Winter9:4512510.618.456.61123
32B4Midseasons12:2502019.021.460.0625
33B4Midseasons13:0501521.425.646.9999
34B4Midseasons12:1502221.424.948.91037
35B4Winter13:0511010.418.849.2894
36B4Winter13:2011710.420.154.61768
37C3Midseasons13:2001624.524.831.2921
38C3Midseasons12:1502924.524.140.61266
39C3Midseasons12:3501722.323.835.31108
40C3Winter9:201318.920.554.31355
41C3Winter12:2003113.822.548.01720
42C3Winter13:3001413.822.843.81374
Table 4. Average values of health symptoms in case studies with closed windows. Legend: Case study (CS), Climate zone (CZ), Dizziness (D), Dry Skin (DS), Itchiness (I), Nausea (N), Nasal congestion (NC), Eye Irritation (EI), Headache (H), Chest oppression (CO), Tiredness (T).
Table 4. Average values of health symptoms in case studies with closed windows. Legend: Case study (CS), Climate zone (CZ), Dizziness (D), Dry Skin (DS), Itchiness (I), Nausea (N), Nasal congestion (NC), Eye Irritation (EI), Headache (H), Chest oppression (CO), Tiredness (T).
CSCZDsDSINNCEIHCOT
1A40.100.120.010.050.150.070.100.070.08
2A40.000.000.000.000.000.000.000.000.00
3A40.000.000.000.000.000.000.000.000.00
4B40.180.230.100.080.060.070.140.100.22
5B40.000.000.000.000.000.000.000.000.00
6B40.000.000.000.000.000.000.000.000.00
7B40.000.000.000.000.000.000.000.000.00
8B40.000.000.000.000.000.000.000.000.00
9B40.000.000.000.000.000.000.000.000.00
10B40.000.000.000.000.000.000.000.000.00
11B40.000.000.000.000.000.000.000.000.00
12B40.090.010.000.000.010.000.040.010.06
13B40.410.200.180.080.100.180.350.210.37
14B40.410.240.140.150.160.130.290.280.28
15B40.360.220.180.180.110.160.220.220.31
16C30.000.000.000.000.000.000.000.000.00
17C30.000.000.000.000.000.000.000.000.00
18C30.440.310.160.160.160.180.340.220.36
19C30.380.360.240.190.240.120.310.130.41
20C30.480.300.160.230.200.200.370.330.42
21C30.550.320.150.200.190.130.330.150.42
22C30.380.260.130.070.120.100.270.140.34
23C30.400.320.190.070.160.130.270.160.35
24C30.340.280.240.110.160.130.280.220.42
25C30.410.200.050.140.120.110.280.180.32
26C30.510.310.130.190.090.200.240.140.36
27C40.280.380.250.260.280.070.150.170.47
28C40.230.270.240.150.230.130.150.240.31
Table 5. Average values of health symptoms in case studies with open windows. Legend: Case study (CS), Climate zone (CZ), Dizziness (D), Dry Skin (DS), Itchiness (I), Nausea (N), Nasal congestion (NC), Eye Irritation (EI), Headache (H), Chest oppression (CO), Tiredness (T).
Table 5. Average values of health symptoms in case studies with open windows. Legend: Case study (CS), Climate zone (CZ), Dizziness (D), Dry Skin (DS), Itchiness (I), Nausea (N), Nasal congestion (NC), Eye Irritation (EI), Headache (H), Chest oppression (CO), Tiredness (T).
CSCZDDSINNCEIHCOT
29A40.130.110.030.080.140.030.120.050.08
30B40.230.180.100.070.070.110.190.080.25
31B40.000.000.000.000.000.000.000.000.00
32B40.080.000.000.000.000.000.020.000.07
33B40.370.440.240.160.190.210.430.240.24
34B40.430.250.150.080.130.100.280.160.37
35B40.330.270.070.070.090.090.200.200.29
36B40.250.260.140.100.080.130.310.180.29
37C30.430.430.160.320.170.190.350.360.45
38C30.310.410.210.190.210.110.260.210.37
39C30.400.360.140.090.180.130.330.250.33
40C30.390.310.110.250.150.160.410.240.33
41C30.430.320.290.210.240.220.310.170.29
42C30.340.260.120.050.310.060.200.170.28
Table 6. Average values and standard deviation of n50.
Table 6. Average values and standard deviation of n50.
Climatic ZoneMean n50 (h−1)Standard Deviation
A46.530.94
C36.121.67
B47.892.45
C47.60.56
Mean6.972.06
Table 7. Correlations between environmental parameters and n50.
Table 7. Correlations between environmental parameters and n50.
n50 (Closed Windows)n50 (Open Windows)
Temperature Outdoor−0.270.12
Temperature Indoor −0.130.18
Wind velocity Indoor−0.280.08
CO2 concentration Indoor0.12−0.19
Table 8. Correlations between CO2 concentration and student symptomatology.
Table 8. Correlations between CO2 concentration and student symptomatology.
SymptomatologyCO2 Concentration
(Closed Windows)
CO2 Concentration-
(Open Windows)
Dizziness0.401 (R2 = 0.16)0.130 (R2 = 0.02)
Dry skin0.469 (R2 = 0.22)0.142 (R2 = 0.02)
Itchiness0.554 (R2 = 0.31)0.369 (R2 = 0.14)
Nausea0.523 (R2 = 0.27)0.171 (R2 = 0.03)
Nasal congestion0.441 (R2 = 0.30)0.319 (R2 = 0.10)
Eye irritation0.462 (R2 = 0.21)0.303 (R2 = 0.09)
Headache0.346 (R2 = 0.12)0.263 (R2 = 0.07)
Chest oppression0.551 (R2 = 0.20)−0.002 (R2 = 0.10)
Tiredness0.500 (R2 = 0.25)0.133 (R2 = 0.01)

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MDPI and ACS Style

Fernández-Agüera, J.; Campano, M.Á.; Domínguez-Amarillo, S.; Acosta, I.; Sendra, J.J. CO2 Concentration and Occupants’ Symptoms in Naturally Ventilated Schools in Mediterranean Climate. Buildings 2019, 9, 197. https://doi.org/10.3390/buildings9090197

AMA Style

Fernández-Agüera J, Campano MÁ, Domínguez-Amarillo S, Acosta I, Sendra JJ. CO2 Concentration and Occupants’ Symptoms in Naturally Ventilated Schools in Mediterranean Climate. Buildings. 2019; 9(9):197. https://doi.org/10.3390/buildings9090197

Chicago/Turabian Style

Fernández-Agüera, Jesica, Miguel Ángel Campano, Samuel Domínguez-Amarillo, Ignacio Acosta, and Juan José Sendra. 2019. "CO2 Concentration and Occupants’ Symptoms in Naturally Ventilated Schools in Mediterranean Climate" Buildings 9, no. 9: 197. https://doi.org/10.3390/buildings9090197

APA Style

Fernández-Agüera, J., Campano, M. Á., Domínguez-Amarillo, S., Acosta, I., & Sendra, J. J. (2019). CO2 Concentration and Occupants’ Symptoms in Naturally Ventilated Schools in Mediterranean Climate. Buildings, 9(9), 197. https://doi.org/10.3390/buildings9090197

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