Access the full text.
Sign up today, get DeepDyve free for 14 days.
P. Rajagopalan, M. Andamon, J. Woo (2021)
Year long monitoring of indoor air quality and ventilation in school classrooms in Victoria, AustraliaArchitectural Science Review, 65
(2023a)
Indoor air quality (IAQ) | US EPA
(2023f)
Sulfur dioxide (SO2) pollution: sulfur dioxide basics
Xuefeng Xu, Liang Peng, Bingsong Yu, Zhenlei Chen, Fan Shi, Haitao He (2022)
Study on the Influence of Fresh Air System of Range Hood on Kitchen Air QualityAtmosphere
Qiang Wang, Daizhi An, Zhengquan Yuan, Rubao Sun, Wei Lu, Lili Wang (2022)
A field investigation into the characteristics and formation mechanisms of particles during the operation of laser printers and photocopiers.Journal of environmental sciences, 126
Salik Nazir, Shakeel Simnani, R. Mishra, T. Sharma, Sajad Masood (2020)
Simultaneous measurements of radon, thoron and their progeny for inhalation dose assessment in indoors of Srinagar, J&K, IndiaJournal of Radioanalytical and Nuclear Chemistry, 325
M.B. Miles, A.M. Huberman, J. Saldana (2019)
Qualitative Data Analysis: A Methods Sourcebook
Joseph Seguel, Richard Merrill, Dana Seguel, Anthony Campagna (2017)
Indoor Air QualityAmerican Journal of Lifestyle Medicine, 11
N. Walliman (2011)
Research Methods: Basics
Ling Wang, Qiuyi Yang, Qingqing Sun (2022)
Association between Air Quality and Children’s Restorative Experience: A Systematic ReviewAtmosphere
H. Abdullah, H. Alibaba (2022)
A Performance-Based Window Design and Evaluation Model for Naturally Ventilated OfficesBuildings
V. Tran, Duckshin Park, Young-Chul Lee (2020)
Indoor Air Pollution, Related Human Diseases, and Recent Trends in the Control and Improvement of Indoor Air QualityInternational Journal of Environmental Research and Public Health, 17
J. Laue (2018)
ASHRAE 62.1: using the ventilation rate procedure
J. Kowalska, M. Szewczyńska, M. Pośniak (2015)
Measurements of chlorinated volatile organic compounds emitted from office printers and photocopiersEnvironmental Science and Pollution Research, 22
(2023b)
Particulate matter (PM) basics | US EPA
J. Kowalska, M. Szewczyńska, M. Pośniak (2014)
Measurements of chlorinated volatile organic compounds emitted from office printers and photocopiersEnvironmental Science and Pollution Research International, 22
I. Grgić, Jožica Bratec, M. Rogač (2016)
Indoor Nanoparticles Measurements in Workplace Environment: The Case of Printing and Photocopy Center.Acta chimica Slovenica, 63 2
(2020)
Quit blaming ASHRAE standard 62.1 for 1000 ppm CO2
Wonyoung Yang, H. Moon (2019)
Combined effects of acoustic, thermal, and illumination conditions on the comfort of discrete senses and overall indoor environmentBuilding and Environment
D. Khovalyg, O. Kazanci, H. Halvorsen, Ida Gundlach, W. Bahnfleth, J. Toftum, B. Olesen (2020)
Critical review of standards for indoor thermal environment and air qualityEnergy and Buildings, 213
M. Mannan, Sami Al‐Ghamdi (2021)
Indoor Air Quality in Buildings: A Comprehensive Review on the Factors Influencing Air Pollution in Residential and Commercial StructureInternational Journal of Environmental Research and Public Health, 18
Javier González-Martín, N. Kraakman, Cristina Pérez, R. Lebrero, R. Muñoz (2021)
A state-of-the-art review on indoor air pollution and strategies for indoor air pollution control.Chemosphere, 262
Heidi Salonen, T. Salthammer, L. Morawska (2020)
Human exposure to indoor air contaminants in indoor sports environments.Indoor air
(2023d)
Ozone pollution and your patients’ health: what is ozone?
Thi Nguyen, G. Johnson, S. Bell, L. Knibbs (2022)
A Systematic Literature Review of Indoor Air Disinfection Techniques for Airborne Bacterial Respiratory PathogensInternational Journal of Environmental Research and Public Health, 19
A. Nandan, N. Siddiqui, Pankaj Kumar (2020)
Estimation of indoor air pollutant during photocopy/printing operation: a computational fluid dynamics (CFD)-based studyEnvironmental Geochemistry and Health, 42
A. Faraji, M. Rashidi, Fatemeh Rezaei, P. Rahnamayiezekavat (2023)
A Meta-Synthesis Review of Occupant Comfort Assessment in Buildings (2002–2022)Sustainability
Y. Zhang (2004)
Indoor Air Quality Engineering
(2023c)
Basic information about carbon monoxide (CO) outdoor air pollution
Yuxuan Zeng, R. Xie, Jianping Cao, Zhixiong Chen, Qingjuan Fan, Biyuan Liu, Xiaoyin Lian, Haibao Huang (2020)
Simultaneous removal of multiple indoor-air pollutants using a combined process of electrostatic precipitation and catalytic decompositionChemical Engineering Journal, 388
E. Livingston (2004)
The mean and standard deviation: what does it all mean?The Journal of surgical research, 119 2
Xiao-yang Liu (2021)
ASTM and ASHRAE Standards for the Assessment of Indoor Air QualityHandbook of Indoor Air Quality
Jing Yuan, Xiaohui Zhao, G. Segun, M. Vakili, Lexuan Zhong (2021)
Indoor Environmental Health Assessment in Eco-Building and Its Case StudyAtmosphere
N. Agarwal, C. Meena, B. Raj, Lohit Saini, Ashok V, N. Gopalakrishnan, Anuj Kumar, N. Balam, Tabish Alam, N. Kapoor, Vivek Aggarwal (2021)
Indoor air quality improvement in COVID-19 pandemic: ReviewSustainable Cities and Society, 70
Mingpu Wang, G. Yao, Yujia Sun, Yang Yang, Rui Deng (2022)
Exposure to construction dust and health impacts - A review.Chemosphere
(2023)
Featured Education in Indoor Air Quality
S. Abdul-Wahab, Stephen En, A. Elkamel, L. Ahmadi, K. Yetilmezsoy (2015)
A review of standards and guidelines set by international bodies for the parameters of indoor air qualityAtmospheric Pollution Research, 6
W. Anake, Esther Nnamani (2023)
Indoor air quality in day-care centres: a global reviewAir Quality, Atmosphere, & Health, 16
D. Wyon (2004)
The effects of indoor air quality on performance and productivity.Indoor air, 14 Suppl 7
(2023e)
Nitrogen dioxide (NO2) pollution: basic information about NO2
E. Langiano, M. Ferrara, L. Falese, L. Lanni, P. Diotaiuti, T. Libero, E. Vito (2024)
Assessment of Indoor Air Quality in School Facilities: An Educational Experience of Pathways for Transversal Skills and Orientation (PCTO)Sustainability
(2021)
WHO global air quality guidelines: particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide
Yrjö Myllylä, J. Kaivo‐oja (2024)
A hybrid foresight study of the environmental reference laboratory system in Finland: a foresight study for the Government of FinlandEuropean Journal of Futures Research, 12
Building operations and human activities indoors continuously affect air quality, contaminating the air and sometimes exceeding permissible limits which can be health threatening either in the short or long time. This implies a need for strict awareness and compliance with air quality standards, particularly in workplaces prone to air contaminants emissions. This study aims to evaluate printing-related pollutant concentrations and their effects on indoor air quality (IAQ). The study investigated a printing press's total volatile organic compounds (TVOC), particulate matter (PM), carbon monoxide and carbon dioxide emissions.Design/methodology/approachThis study used mainly an experimental research design supported by physical assessment by identifying the major printing-related pollutants, assessing the existing situation and measuring pollutant concentration levels using literature reviews, walkthrough inspections and experiments, respectively. The measurements were conducted in two scenarios: with and without printing activities, and the results were compared with relevant standards and guidelines.FindingsThe outcomes indicate that TVOC concentration reaches 120 ppb during printing and binding activities, exceeding the 75 ppb acceptable limit based on the time-weighted average. The PM2.5 concentrations reach 49 µg/m3 and PM10 up to 150 µg/m3, exceeding acceptable levels given by the US Environmental Protection Agency (EPA), which are 35 µg/m3 and 150 µg/m3 for PM2.5 and PM10, respectively. These high concentrations of TVOC and PM indicate a significant risk to the health of building occupants, particularly those with respiratory conditions. PM concentrations do not exceed permissible levels when no printing or bookbinding occurs, suggesting that printing-related activities can contribute to elevated TVOC and PM concentrations.Social implicationsThe social implication of the study lies in its ability to promote awareness among workers and improve their well-being which in turn relates to productivity. The study outcome could also encourage businesses to adopt more responsible environmental and social practices as part of corporate social responsibility practices.Originality/valueThe study's findings, which highlight the need for improved ventilation in printing halls, have the potential to significantly benefit building system designers, facility managers, policymakers and decision-makers. By providing information and theoretical support, the research can help integrate policies that regulate IAQ by reducing pollutant concentrations. This protects workers' health and helps update and enforce stricter IAQ regulations for industrial operations.
Facilities – Emerald Publishing
Published: Nov 13, 2024
Keywords: Indoor air quality; Printing; Pollutants; Concentrations; Contaminants; Standards
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.