Mapping Occupational Hazards with a Multi-sensor Network in a Heavy-Vehicle Manufacturing Facility

Due to their small size, low-power demands, and customizability, low-cost sensors can be deployed in collections that are spatially distributed in the environment, known as sensor networks. The literature contains examples of such networks in the ambient environment; this article describes the development and deployment of a 40-node multi-hazard network, constructed with low-cost sensors for particulate matter (SHARP GP2Y1010AU0F), carbon monoxide (Alphasense CO-B4), oxidizing gases (Alphasense OX-B421), and noise (developed in-house) in a heavy-vehicle manufacturing facility. Network nodes communicated wirelessly with a central database in order to record hazard measurements at 5-min intervals. Here, we report on the temporal and spatial measurements from the network, precision of network measurements, and accuracy of network measurements with respect to field reference instruments through 8 months of continuous deployment. During typical production periods, 1-h mean hazard levels ± standard deviation across all monitors for particulate matter (PM), carbon monoxide (CO), oxidizing gases (OX), and noise were 0.62 ± 0.2 mg m-3, 7 ± 2 ppm, 155 ± 58 ppb, and 82 ± 1 dBA, respectively. We observed clear diurnal and weekly temporal patterns for all hazards and daily, hazard-specific spatial patterns attributable to general manufacturing processes in the facility. Processes associated with the highest hazard levels were machining and welding (PM and noise), staging (CO), and manual and robotic welding (OX). Network sensors exhibited varying degrees of precision with 95% of measurements among three collocated nodes within 0.21 mg m-3 for PM, 0.4 ppm for CO, 9 ppb for OX, and 1 dBA for noise of each other. The median percent bias with reference to direct-reading instruments was 27%, 11%, 45%, and 1%, for PM, CO, OX, and noise, respectively. This study demonstrates the successful long-term deployment of a multi-hazard sensor network in an industrial manufacturing setting and illustrates the high temporal and spatial resolution of hazard data that sensor and monitor networks are capable of. We show that network-derived hazard measurements offer rich datasets to comprehensively assess occupational hazards. Our network sets the stage for the characterization of occupational exposures on the individual level with wireless sensor networks.

[1]  S. Katharine Hammond,et al.  Mapping Particulate Matter at the Body Weld Department in an Automobile Assembly Plant , 2010, Journal of occupational and environmental hygiene.

[2]  Thomas M. Peters,et al.  Sensor Selection to Improve Estimates of Particulate Matter Concentration from a Low-Cost Network , 2018, Sensors.

[3]  A. Kumar,et al.  Energy Efficient and Low-Cost Indoor Environment Monitoring System Based on the IEEE 1451 Standard , 2011, IEEE Sensors Journal.

[4]  Duk-Dong Lee,et al.  Environmental gas sensors , 2001, IEEE Sensors Journal.

[5]  A. Bartoňová,et al.  On the use of small and cheaper sensors and devices for indicative citizen-based monitoring of respirable particulate matter. , 2015, Environmental pollution.

[6]  Jahangir Ikram,et al.  View: implementing low cost air quality monitoring solution for urban areas , 2012, Environmental Systems Research.

[7]  William A Heitbrink,et al.  Characterization and Mapping of Very Fine Particles in an Engine Machining and Assembly Facility , 2007, Journal of occupational and environmental hygiene.

[8]  Kirsten A Koehler,et al.  Optimizing a Sensor Network with Data from Hazard Mapping Demonstrated in a Heavy-Vehicle Manufacturing Facility , 2018, Annals of work exposures and health.

[9]  M. Harper Assessing workplace chemical exposures: the role of exposure monitoring. , 2004, Journal of environmental monitoring : JEM.

[10]  A. Lewis,et al.  Validate personal air-pollution sensors , 2016, Nature.

[11]  Darrin K. Ott,et al.  Passive sampling to capture spatial variability in PM10–2.5 , 2008 .

[12]  D. Dockery,et al.  Health Effects of Fine Particulate Air Pollution: Lines that Connect , 2006, Journal of the Air & Waste Management Association.

[13]  John Heidemann,et al.  Using Geospatial Information in Sensor Networks , 2001, MobiCom 2001.

[14]  N B Hampson,et al.  Carbon monoxide poisoning--a public health perspective. , 2000, Toxicology.

[15]  Jun Zhu,et al.  STATIC AND ROVING SENSOR DATA FUSION FOR SPATIO-TEMPORAL HAZARD MAPPING WITH APPLICATION TO OCCUPATIONAL EXPOSURE ASSESSMENT. , 2017, The annals of applied statistics.

[16]  S Selvin,et al.  The effect of autocorrelation on the estimation of workers' daily exposures. , 1989, American Industrial Hygiene Association journal.

[17]  Xiaoxing Liu,et al.  Low-Cost, Distributed Environmental Monitors for Factory Worker Health , 2018, Sensors.

[18]  A. Lewis,et al.  Evaluating the performance of low cost chemical sensors for air pollution research. , 2016, Faraday discussions.

[19]  Geb Thomas,et al.  Evaluation of low-cost electro-chemical sensors for environmental monitoring of ozone, nitrogen dioxide, and carbon monoxide , 2018, Journal of occupational and environmental hygiene.

[20]  John V. Crable and David G. Taylor,et al.  NIOSH manual of analytical methods , 2013 .

[21]  Lothar Thiele,et al.  Deriving high-resolution urban air pollution maps using mobile sensor nodes , 2015 .

[22]  Ji Young Park,et al.  Determination of Particle Concentration Rankings by Spatial Mapping of Particle Surface Area, Number, and Mass Concentrations in a Restaurant and a Die Casting Plant , 2010, Journal of occupational and environmental hygiene.

[23]  D. Dockery,et al.  Health Effects of Fine Particulate Air Pollution: Lines that Connect , 2006, Journal of the Air & Waste Management Association.

[24]  D. Dockery Epidemiologic study design for investigating respiratory health effects of complex air pollution mixtures. , 1993, Environmental health perspectives.

[25]  ThieleLothar,et al.  Deriving high-resolution urban air pollution maps using mobile sensor nodes , 2015 .

[26]  M. I. Mead,et al.  Source attribution of air pollution by spatial scale separation using high spatial density networks of low cost air quality sensors , 2015 .

[27]  Qijun Jiang,et al.  Citizen Sensing for Improved Urban Environmental Monitoring , 2016, J. Sensors.

[28]  William A Heitbrink,et al.  The mapping of fine and ultrafine particle concentrations in an engine machining and assembly facility. , 2006, The Annals of occupational hygiene.

[29]  Manuel Aleixandre,et al.  Performance evaluation of amperometric sensors for the monitoring of O3 and NO2 in ambient air at ppb level , 2015 .

[30]  Dae-Sik Lee,et al.  Environmental gas sensors , 2001 .

[31]  S M Rappaport,et al.  An investigation of the dependence of exposure variability on the interval between measurements. , 1994, The Annals of occupational hygiene.

[32]  P. O’Shaughnessy,et al.  Distribution of particle and gas concentrations in Swine gestation confined animal feeding operations. , 2012, The Annals of occupational hygiene.

[33]  Kirsten A Koehler,et al.  Influence of analysis methods on interpretation of hazard maps. , 2013, The Annals of occupational hygiene.

[34]  Walter McDonald,et al.  Health Effects of Ozone , 2003 .

[35]  Michael Hannigan,et al.  Quantification Method for Electrolytic Sensors in Long-Term Monitoring of Ambient Air Quality , 2015, Sensors.

[36]  Geb Thomas,et al.  An inexpensive sensor for noise , 2018, Journal of occupational and environmental hygiene.

[37]  M Luoma,et al.  Autocorrelation and variability of indoor air quality measurements. , 2000, AIHAJ : a journal for the science of occupational and environmental health and safety.

[38]  U. Lerner,et al.  On the feasibility of measuring urban air pollution by wireless distributed sensor networks. , 2015, The Science of the total environment.

[39]  J. Saffell,et al.  Differentiating NO2 and O3 at Low Cost Air Quality Amperometric Gas Sensors , 2016 .

[40]  Airborne Nanoparticle Concentrations in the Manufacturing of Polytetrafluoroethylene (PTFE) Apparel , 2011, Journal of occupational and environmental hygiene.

[41]  Dennis M O'Brien,et al.  Aerosol mapping of a facility with multiple cases of hypersensitivity pneumonitis: demonstration of mist reduction and a possible dose/response relationship. , 2003, Applied occupational and environmental hygiene.

[42]  M. Lippmann Health effects of ozone. A critical review. , 1989, JAPCA.

[43]  Gb Stewart,et al.  The use of electrochemical sensors for monitoring urban air quality in low-cost, high-density networks , 2013 .

[44]  J. Thundiyil,et al.  Clearing the Air: A Review of the Effects of Particulate Matter Air Pollution on Human Health , 2011, Journal of Medical Toxicology.

[45]  Joel Schwartz,et al.  REVIEW OF EPIDEMIOLOGICAL EVIDENCE OF HEALTH EFFECTS OF PARTICULATE AIR POLLUTION , 1995 .

[46]  Tarald O. Kvålseth,et al.  Coefficient of variation: the second-order alternative , 2017 .

[47]  Steffen Loft,et al.  Inhalation of ozone induces DNA strand breaks and inflammation in mice. , 2002, Mutation research.

[48]  G. Hagler,et al.  Community Air Sensor Network (CAIRSENSE) project: evaluation of low-cost sensor performance in a suburban environment in the southeastern United States. , 2016, Atmospheric measurement techniques.

[49]  Alexander Kolovos,et al.  Multi-perspective analysis and spatiotemporal mapping of air pollution monitoring data. , 2010, Environmental science & technology.

[50]  Henning Omre,et al.  Spatial Interpolation Errors for Monitoring Data , 1995 .

[51]  Jun Zhu,et al.  Effects of Data Sparsity and Spatiotemporal Variability on Hazard Maps of Workplace Noise , 2015, Journal of occupational and environmental hygiene.

[52]  E. Snyder,et al.  The changing paradigm of air pollution monitoring. , 2013, Environmental science & technology.

[53]  Charles J. Weschler,et al.  Ozone’s Impact on Public Health: Contributions from Indoor Exposures to Ozone and Products of Ozone-Initiated Chemistry , 2006, Environmental health perspectives.

[54]  L. Morawska,et al.  The rise of low-cost sensing for managing air pollution in cities. , 2015, Environment international.

[55]  E. Seto,et al.  A distributed network of low-cost continuous reading sensors to measure spatiotemporal variations of PM2.5 in Xi'an, China. , 2015, Environmental pollution.

[56]  John Volckens,et al.  Prospects and pitfalls of occupational hazard mapping: 'between these lines there be dragons'. , 2011, The Annals of occupational hygiene.

[57]  W. Passchier,et al.  Noise exposure and public health. , 2000, Environmental health perspectives.

[58]  E. Seto,et al.  The Imperial County Community Air Monitoring Network: A Model for Community-based Environmental Monitoring for Public Health Action , 2017, Environmental health perspectives.

[59]  L. Shang,et al.  The next generation of low-cost personal air quality sensors for quantitative exposure monitoring , 2014 .

[60]  Geb Thomas,et al.  Inter-comparison of low-cost sensors for measuring the mass concentration of occupational aerosols , 2016, Aerosol science and technology : the journal of the American Association for Aerosol Research.

[61]  William A Heitbrink,et al.  Ultrafine and respirable particles in an automotive grey iron foundry. , 2007, The Annals of occupational hygiene.

[62]  M. Kampa,et al.  Human health effects of air pollution. , 2008, Environmental pollution.