Abstract
In multisource industrial scenarios (MSIS) coexist NOAA generating activities with other productive sources of airborne particles, such as parallel processes of manufacturing or electrical and diesel machinery. A distinctive characteristic of MSIS is the spatially complex distribution of aerosol sources, as well as their potential differences in dynamics, due to the feasibility of multi-task configuration at a given time. Thus, the background signal is expected to challenge the aerosol analyzers at a probably wide range of concentrations and size distributions, depending of the multisource configuration at a given time. Monitoring and prediction by using statistical analysis of time series captured by on-line particle analyzersin industrial scenarios, have been proven to be feasible in predicting PNC evolution provided a given quality of net signals (difference between signal at source and background). However the analysis and modelling of non-consistent time series, influenced by low levels of SNR (Signal-Noise Ratio) could build a misleading basis for decision making. In this context, this work explores the use of stochastic models based on ARIMA methodology to monitor and predict exposure values (PNC). The study was carried out in a MSIS where an case study focused on the manufacture of perforated tablets of nano-TiO2 by cold pressing was performed.
Original language | English |
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Article number | 012003 |
Journal | Journal of Physics: Conference Series |
Volume | 617 |
Issue number | 1 |
DOIs | |
Publication status | Published - 26 May 2015 |
Event | 4th International Conference on Safe Production and Use of Nanomaterials, NANOSAFE 2014 - Grenoble, France Duration: 18 Nov 2014 → 20 Nov 2014 |
Keywords
- NOAA
- Multisource industrial scenarios
Project and Funding Information
- Project ID
- info:eu-repo/grantAgreement/EC/FP7/319092/EU/Establishing a process and a platform to support standardization for nanotechnologies implementing the STAIR approach/NANOSTAIR
- info:eu-repo/grantAgreement/EC/FP7/280535/EU/Innovative strategies, methods and tools for occupational risks management of manufactured nanomaterials (MNMs) in the construction industry/SCAFFOLD
- Funding Info
- Research carried out by projects SCAFFOLD and EHS Advance were made possible thanks to_x000D_ funding from European Commission through FP7 (GA 319092) and Basque Country Government_x000D_ through ETORTEK Programme.