Araştırma Makalesi
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Bir Hastanede İç Hava Kalitesinin Araştırılması: Şanlıurfa’dan Örnek Bir Çalışma

Yıl 2019, Cilt: 5 Sayı: 1, 101 - 109, 31.01.2019
https://doi.org/10.21324/dacd.448598

Öz



Çoğu insan zamanlarının %80’ninden fazlasını iç ortamlarda
geçirmektedir. Hastaneler, Türkiye'de önemli bir kamusal alandır. İnsanların hastanelere
diğer kamusal alanlardan çok daha fazla gitmesi hastaneleri önemli bir kurum haline
getirmektedir. Bu çalışmada, Türkiye’nin Şanlıurfa ilinde en çok hasta bakan hastanenin
polikliniklerinde iç hava kalitesi araştırılmıştır.
İç hava kalitesini belirleyen partikül
madde (PM), CO, CO2, sıcaklık ve bağıl nem iç hava kalitesini
belirleyen parametreler olarak değerlendirilmiştir. Ölçülen değerler WHO, ASHAE
gibi uluslararası standartlarla karşılaştırıldığında PM2.5 ve PM10
 
konsantrasyonun
her ikisinin de yüksek değerlerde olduğu poliklinikler sırasıyla genel
cerrahi, üroloji, nöroloji, kalp servisi ve göz hastalıkları olarak
belirlenmiştir. CO2 insanlar tarafından solunum yoluyla yayılan bir
iç hava kirleticisidir. Bu araştırmada CO2 seviyesinin radyoloji,
tomografi, röntgen, ortopedi polikliniği ve acil serviste ASHAE standartlarının
altında olduğu bulunmuşken diğer polikliniklerde standartın üstünde ölçülmüştür.
Sıcaklık ve bağıl nem değerleri tüm polikliniklerde standartlara uygun olmadığı,
CO değerinin tüm polikliniklerde düşük olup standartları sağlamakta olduğu
saptanmıştır
. Yetersiz havalandırma, eksik temizlik, alçak tavan ve
hasta sayısındaki fazlalık polikliniklerde standartların üzerinde değerlere
sebep olan ana etmenler arasında olduğu düşünülmektedir. Eski yapılı hastanelerde,
toz partikülleri, CO2, sıcaklık ve bağıl nem polikliniklerde
çalışanların ve hastaların sağlığı için risk oluşturabileceği saptanmıştır.




Kaynakça

  • Araújo M.B., Alagador D., Cabeza M., Nogués‐Bravo D., Thuiller W., (2011), Climate change threatens European conservation areas, Ecology Letters, 14(5), 484-492.
  • ASHRAE, (2001), The ASHRAE Handbook 2001: Fundamentals, Chapter 8: Thermal Comfort, Atlanta, USA, 544ss.
  • Beelen R.G., Hoek G., van den Brandt P.A., Goldbohm R.A., Fischer P., Schouten L.J., Jerrett M., Hughes E., Armstrong B., Brunekreef B., (2008), Long-term effects of traffic-related air pollution on mortality in a Dutch cohort (NLCS-AIR Study), Environmental Health Perspectives, 116(2), 196–202.
  • Bruce N., Perez-Padilla R., Albalak R., (2000), Indoor air pollution in developing countries: amajor environmental and public health challenge, Bulletin of the World Health Organization, 78(9), 1078-1092.
  • Chaloulakou A., Mavroidis I., Duci A., (2003), Indoor and outdoor carbon monoxide concentration relationships at different microenvironments in the Athens area, Chemosphere, 52(6), 1007-1019.
  • Chamseddine A., El-Fadel M., (2015), Exposure to air pollutants in hospitals: indoor–outdoor correlations, Sustainable Development, 2, 707-716.
  • Chang T., Ren D., Shen Z., Huang Y., Sun J., Cao J., Pan H., (2017), Indoor air pollution levels in decorated residences and public places over Xi’an China, Aerosol and Air Quality Research, 17, 2197-2205.
  • Chen C., Zhao B., (2011), Review of relationship between indoor and outdoor particles: I/O ratio, infiltration factor and penetration factor, Atmospheric Environment, 45(2), 275–288.
  • Ciuzas D., Prasauskas T., Krugly E., Jurelionis A., Seduikyte L., Martuzevicius D., (2016), Indoor air quality management by combined ventilation and air cleaning: An experimental study, Aerosol and Air Quality Research, 16, 2550–2559.
  • Doğan H., (2002), Havalandırma ve İklimlendirme Esasları, Seçkin Yayınevi, Ankara, 231ss.
  • Erdoğan M.S., Yurtseven E., Erginöz E., Vehid S., Köksal S., Yüceokur A.A., (2010), Total Volatile Organic Compounds (TVOC), Carbon Monoxide (Co), Carbon Dioxide (CO2) Concentrations In The Hospital Building of A Medical Faculty In Istanbul, Turkey, Nobel Medicus 2010, 6(3), 66-72.
  • Halios C.H., Helmis C.G., Deligianni K., Vratolis S., Eleftheriadis K., (2013), Determining the ventilation and aerosol deposition rates from routine indoor-air measurements, Environ. Monit. Assess., 186(1), 151–163.
  • Işık E., Çibuk S., (2015), Yemekhaneler ve kantinlerde iç hava kalitesi ile ilgili ölçüm sonuçları ve analizi - Tunceli Üniversitesi örneği, Dicle Üniversitesi Mühendislik Fakültesi Mühendislik Dergisi, 6(1), 39-50.
  • Jovanović M., Vučićević B., Turanjanin V., Živković M., Spasojević V., (2014), Investigation of indoor and outdoor air quality of the classrooms at a school in Serbia, Energy, 77, 42–48.
  • Jung C.C., Wu P.C., Tseng C.H., Su H.J., (2015), Indoor air quality varies with ventilation types and working areas in hospitals, Building and Environment, 85, 190-195.
  • Kim K.H., Kabir E., Kabir S., (2015), A review on the human health impact of airborne particulate matter, Environment International, 74, 136-143.
  • Leung M., Chan A.H.S., (2006), Control and management of hospital indoor air quality, Medical Science Monitor., 12(3), SR17-23.
  • Li R., Fu H., Hu Q., Li C., Zhang L., Chen J., Mellouki A.W., (2017), Physiochemical characteristics of aerosol particles in the typical microenvironment of hospital in Shanghai, China, Science of The Total Environment, 580, 651-659.
  • Lu C.Y., Lin J.M., Chen Y.Y., Chen Y.C., (2015), Building-related symptoms among office employees associated with indoor carbon dioxide and total volatile organic compounds, Int. J. Environ Res Public Health., 12(6), 5833–5845.
  • Lu C.Y., Kang S.Y., Liu S.H., Mai C.W., Tseng C.H., (2016), Controlling Indoor Air Pollution from Moxibustion, International Journal of Environmental Research and Public Health, 13(6), E612.
  • Lu C.Y., Ma Y.C., Lin J.M., Chuang C.Y., Sung F.C., (2007a), Oxidative DNA damage estimated by urinary 8-hydroxydeoxyguanosine and indoor air pollution among non-smoking office employees, Environmental Research, 103(3), 331–337.
  • Lu C.Y., Ma Y.C., Lin J.M., Li C.Y., Lin R.S., Sung F.C., (2007b), Oxidative stress associated with indoor air pollution and sick building syndrome-related symptoms among office workers in Taiwan, Inhalation Toxicology, 19(1), 57–65.
  • McClellan R.O., (2000), Particle interactions with the respiratory tract, In: Particle–Lung Interactions, (Ed.), Peter G., and Heyder J., CRC Press, New York, USA, 823ss.
  • Morman S.A., Plumlee G.S., (2013), The role of airborne mineral dusts in human disease, Aeolian Research, 9, 203-212.
  • Oliver L.C., Shackleton B.W., (1998), The indoor air we breathe, Public Health Reports,113(5), 398-409.
  • Pope III C.A., Burnett R.T., Thun M.J., Calle E.E., Krewski D., Ito K., Thurston G.D., (2002), Lung cancer, cardiopulmonary mortality, and long-term exposure to fine particulate air pollution, Journal of the American Medical Association, 287(9), 1132–1141.
  • Recknagel-Sprenger S., (2003), Isıtma ve Klima Tekniği El Kitabı 97/98, TTMD, İstanbul.
  • Riediker M., Cascio W.E., Griggs T.R., Herbst M.C., Bromberg P.A., Neas L., Williams R.W., Devlin R.B., (2004), Particulate matter exposure in cars is associated with cardiovascular effects in healthy young men, American Journal of Respiratory and Critical Care Medicine, 169(8), 934-940.
  • Seppänen O.A., Fisk W.J., Mendell M.J., (1999), Association of ventilation rates and CO2 concentrations with health and other responses in commercial and institutional buildings, Indoor Air., 9(4), 226-252.
  • Shy C.G., Hsu Y.C., Shih S.I., Chuang K.P., Lin C.W., Wu C.W., Chuang C.Y., Chao H.R., (2015), Indoor level of polybrominated diphenyl ethers in the home environment and assessment of human health risks, Aerosol and Air Quality Research, 15(4), 1494–1505.
  • Stephen E., Mbuligwe G., Kassenga R., (1997), Automobile air pollution in Dar es Salaam City, Tanzania, Science of the total Environment, 199(3), 227-235.
  • Vilcekova S., Meciarova L., Burdov E. K., Katunska J., Kosicanova D., Doroudiani S., (2017), Indoor environmental quality of classrooms and occupants' comfort in a special education school in Slovak Republic, Building and Environment, 120, 29-40.
  • Wang X., Bi X., Sheng G., Fu J., (2006), Hospital indoor PM10/PM2. 5 and associated trace elements in Guangzhou, China, Science of the Total Environment, 366(1), 124-135.
  • WHO, (2000), Air Quality Guidelines for Europe, Second Edition, WHO Regional Publications European Series No. 91, http://www.euro.who.int/__data/assets/pdf_file/0005/74732/E71922.pdf, [Access 27 July 2018].
  • Yang Y., (2017), Numerical study of the particle penetration coefficient of multibended building crack, Aerosol and Air Quality Research, 17(1), 290–301.
  • Zhang X.Y., Wang Y.Q., Zhang X.C., Guo W., Gong S.L., (2008), Carbonaceous aerosol composition over various regions of China during 2006, Journal of Geophysical Research, 113:D14111, 1-10.

Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey

Yıl 2019, Cilt: 5 Sayı: 1, 101 - 109, 31.01.2019
https://doi.org/10.21324/dacd.448598

Öz



Most
people spent more than %80 of their time indoors. In Turkey, hospitals are
prominent governmental places. Its importance
becomes from more visits than others. An investigation about the interior air
quality across the polyclinics of one of the most visited hospital of Şanlıurfa,
Turkey, was conducted in this study. Indoor air quality in terms of PM, CO, CO2,
temperature and relative humidity was investigated. The performed measurements
were revealed that the levels of PM2.5 and PM10 in
surgery, urology, neurology, heart surgeon and eye diseases
polyclinic
were higher than the threshold
limits in international standards set by WHO and ASHAE. CO2, a
surrogate for indoor pollutants emitted by humans. In this research, CO2
was found to be under the standards in radiology, tomography, X-ray,
orthopedics polyclinics and emergency services. Conversely, it was measured
above the standards across the other polyclinics. Temperature and relative
humidity were found unsuitable; CO was found to meet the standards. The
significantly high rates were considered as a result of inadequate ventilation,
lack of proper cleaning, low ceiling and crowd of patients. The old age of the
building could create risk of dust particles, CO2, temperature,
humidity in the hospital for the health of the staff and patients visiting the
polyclinics
.




Kaynakça

  • Araújo M.B., Alagador D., Cabeza M., Nogués‐Bravo D., Thuiller W., (2011), Climate change threatens European conservation areas, Ecology Letters, 14(5), 484-492.
  • ASHRAE, (2001), The ASHRAE Handbook 2001: Fundamentals, Chapter 8: Thermal Comfort, Atlanta, USA, 544ss.
  • Beelen R.G., Hoek G., van den Brandt P.A., Goldbohm R.A., Fischer P., Schouten L.J., Jerrett M., Hughes E., Armstrong B., Brunekreef B., (2008), Long-term effects of traffic-related air pollution on mortality in a Dutch cohort (NLCS-AIR Study), Environmental Health Perspectives, 116(2), 196–202.
  • Bruce N., Perez-Padilla R., Albalak R., (2000), Indoor air pollution in developing countries: amajor environmental and public health challenge, Bulletin of the World Health Organization, 78(9), 1078-1092.
  • Chaloulakou A., Mavroidis I., Duci A., (2003), Indoor and outdoor carbon monoxide concentration relationships at different microenvironments in the Athens area, Chemosphere, 52(6), 1007-1019.
  • Chamseddine A., El-Fadel M., (2015), Exposure to air pollutants in hospitals: indoor–outdoor correlations, Sustainable Development, 2, 707-716.
  • Chang T., Ren D., Shen Z., Huang Y., Sun J., Cao J., Pan H., (2017), Indoor air pollution levels in decorated residences and public places over Xi’an China, Aerosol and Air Quality Research, 17, 2197-2205.
  • Chen C., Zhao B., (2011), Review of relationship between indoor and outdoor particles: I/O ratio, infiltration factor and penetration factor, Atmospheric Environment, 45(2), 275–288.
  • Ciuzas D., Prasauskas T., Krugly E., Jurelionis A., Seduikyte L., Martuzevicius D., (2016), Indoor air quality management by combined ventilation and air cleaning: An experimental study, Aerosol and Air Quality Research, 16, 2550–2559.
  • Doğan H., (2002), Havalandırma ve İklimlendirme Esasları, Seçkin Yayınevi, Ankara, 231ss.
  • Erdoğan M.S., Yurtseven E., Erginöz E., Vehid S., Köksal S., Yüceokur A.A., (2010), Total Volatile Organic Compounds (TVOC), Carbon Monoxide (Co), Carbon Dioxide (CO2) Concentrations In The Hospital Building of A Medical Faculty In Istanbul, Turkey, Nobel Medicus 2010, 6(3), 66-72.
  • Halios C.H., Helmis C.G., Deligianni K., Vratolis S., Eleftheriadis K., (2013), Determining the ventilation and aerosol deposition rates from routine indoor-air measurements, Environ. Monit. Assess., 186(1), 151–163.
  • Işık E., Çibuk S., (2015), Yemekhaneler ve kantinlerde iç hava kalitesi ile ilgili ölçüm sonuçları ve analizi - Tunceli Üniversitesi örneği, Dicle Üniversitesi Mühendislik Fakültesi Mühendislik Dergisi, 6(1), 39-50.
  • Jovanović M., Vučićević B., Turanjanin V., Živković M., Spasojević V., (2014), Investigation of indoor and outdoor air quality of the classrooms at a school in Serbia, Energy, 77, 42–48.
  • Jung C.C., Wu P.C., Tseng C.H., Su H.J., (2015), Indoor air quality varies with ventilation types and working areas in hospitals, Building and Environment, 85, 190-195.
  • Kim K.H., Kabir E., Kabir S., (2015), A review on the human health impact of airborne particulate matter, Environment International, 74, 136-143.
  • Leung M., Chan A.H.S., (2006), Control and management of hospital indoor air quality, Medical Science Monitor., 12(3), SR17-23.
  • Li R., Fu H., Hu Q., Li C., Zhang L., Chen J., Mellouki A.W., (2017), Physiochemical characteristics of aerosol particles in the typical microenvironment of hospital in Shanghai, China, Science of The Total Environment, 580, 651-659.
  • Lu C.Y., Lin J.M., Chen Y.Y., Chen Y.C., (2015), Building-related symptoms among office employees associated with indoor carbon dioxide and total volatile organic compounds, Int. J. Environ Res Public Health., 12(6), 5833–5845.
  • Lu C.Y., Kang S.Y., Liu S.H., Mai C.W., Tseng C.H., (2016), Controlling Indoor Air Pollution from Moxibustion, International Journal of Environmental Research and Public Health, 13(6), E612.
  • Lu C.Y., Ma Y.C., Lin J.M., Chuang C.Y., Sung F.C., (2007a), Oxidative DNA damage estimated by urinary 8-hydroxydeoxyguanosine and indoor air pollution among non-smoking office employees, Environmental Research, 103(3), 331–337.
  • Lu C.Y., Ma Y.C., Lin J.M., Li C.Y., Lin R.S., Sung F.C., (2007b), Oxidative stress associated with indoor air pollution and sick building syndrome-related symptoms among office workers in Taiwan, Inhalation Toxicology, 19(1), 57–65.
  • McClellan R.O., (2000), Particle interactions with the respiratory tract, In: Particle–Lung Interactions, (Ed.), Peter G., and Heyder J., CRC Press, New York, USA, 823ss.
  • Morman S.A., Plumlee G.S., (2013), The role of airborne mineral dusts in human disease, Aeolian Research, 9, 203-212.
  • Oliver L.C., Shackleton B.W., (1998), The indoor air we breathe, Public Health Reports,113(5), 398-409.
  • Pope III C.A., Burnett R.T., Thun M.J., Calle E.E., Krewski D., Ito K., Thurston G.D., (2002), Lung cancer, cardiopulmonary mortality, and long-term exposure to fine particulate air pollution, Journal of the American Medical Association, 287(9), 1132–1141.
  • Recknagel-Sprenger S., (2003), Isıtma ve Klima Tekniği El Kitabı 97/98, TTMD, İstanbul.
  • Riediker M., Cascio W.E., Griggs T.R., Herbst M.C., Bromberg P.A., Neas L., Williams R.W., Devlin R.B., (2004), Particulate matter exposure in cars is associated with cardiovascular effects in healthy young men, American Journal of Respiratory and Critical Care Medicine, 169(8), 934-940.
  • Seppänen O.A., Fisk W.J., Mendell M.J., (1999), Association of ventilation rates and CO2 concentrations with health and other responses in commercial and institutional buildings, Indoor Air., 9(4), 226-252.
  • Shy C.G., Hsu Y.C., Shih S.I., Chuang K.P., Lin C.W., Wu C.W., Chuang C.Y., Chao H.R., (2015), Indoor level of polybrominated diphenyl ethers in the home environment and assessment of human health risks, Aerosol and Air Quality Research, 15(4), 1494–1505.
  • Stephen E., Mbuligwe G., Kassenga R., (1997), Automobile air pollution in Dar es Salaam City, Tanzania, Science of the total Environment, 199(3), 227-235.
  • Vilcekova S., Meciarova L., Burdov E. K., Katunska J., Kosicanova D., Doroudiani S., (2017), Indoor environmental quality of classrooms and occupants' comfort in a special education school in Slovak Republic, Building and Environment, 120, 29-40.
  • Wang X., Bi X., Sheng G., Fu J., (2006), Hospital indoor PM10/PM2. 5 and associated trace elements in Guangzhou, China, Science of the Total Environment, 366(1), 124-135.
  • WHO, (2000), Air Quality Guidelines for Europe, Second Edition, WHO Regional Publications European Series No. 91, http://www.euro.who.int/__data/assets/pdf_file/0005/74732/E71922.pdf, [Access 27 July 2018].
  • Yang Y., (2017), Numerical study of the particle penetration coefficient of multibended building crack, Aerosol and Air Quality Research, 17(1), 290–301.
  • Zhang X.Y., Wang Y.Q., Zhang X.C., Guo W., Gong S.L., (2008), Carbonaceous aerosol composition over various regions of China during 2006, Journal of Geophysical Research, 113:D14111, 1-10.
Toplam 36 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Araştırma Makalesi
Yazarlar

Tuba Rastgeldi Doğan 0000-0002-8246-388X

Yayımlanma Tarihi 31 Ocak 2019
Gönderilme Tarihi 27 Temmuz 2018
Kabul Tarihi 28 Eylül 2018
Yayımlandığı Sayı Yıl 2019Cilt: 5 Sayı: 1

Kaynak Göster

APA Rastgeldi Doğan, T. (2019). Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey. Doğal Afetler Ve Çevre Dergisi, 5(1), 101-109. https://doi.org/10.21324/dacd.448598
AMA Rastgeldi Doğan T. Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey. Doğ Afet Çev Derg. Ocak 2019;5(1):101-109. doi:10.21324/dacd.448598
Chicago Rastgeldi Doğan, Tuba. “Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey”. Doğal Afetler Ve Çevre Dergisi 5, sy. 1 (Ocak 2019): 101-9. https://doi.org/10.21324/dacd.448598.
EndNote Rastgeldi Doğan T (01 Ocak 2019) Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey. Doğal Afetler ve Çevre Dergisi 5 1 101–109.
IEEE T. Rastgeldi Doğan, “Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey”, Doğ Afet Çev Derg, c. 5, sy. 1, ss. 101–109, 2019, doi: 10.21324/dacd.448598.
ISNAD Rastgeldi Doğan, Tuba. “Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey”. Doğal Afetler ve Çevre Dergisi 5/1 (Ocak 2019), 101-109. https://doi.org/10.21324/dacd.448598.
JAMA Rastgeldi Doğan T. Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey. Doğ Afet Çev Derg. 2019;5:101–109.
MLA Rastgeldi Doğan, Tuba. “Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey”. Doğal Afetler Ve Çevre Dergisi, c. 5, sy. 1, 2019, ss. 101-9, doi:10.21324/dacd.448598.
Vancouver Rastgeldi Doğan T. Investigation of Indoor Air Quality in a Hospital: A Case Study from Şanlıurfa, Turkey. Doğ Afet Çev Derg. 2019;5(1):101-9.

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