Alapfogalmak
An analytical model is developed to assess the probability of workers getting infected by dangerous airborne pathogens through direct contact with infected individuals and indirect contact with contaminated surfaces and environments in industrial facilities.
Kivonat
The paper presents an analytical model to assess the risk of workers getting infected by dangerous airborne pathogens in industrial environments. The model considers two main transmission routes: 1) direct infection through inhalation of droplets from infected individuals, and 2) indirect infection through contact with contaminated surfaces or environments.
The direct transmission is modeled using a simplified diffusion equation to describe the density of droplets in the air around an infected individual. The indirect transmission is modeled through two mechanisms: 1) inhalation of small droplets and aerosols from contaminated environmental air, and 2) contact with contaminated surfaces.
The probability of infection is calculated for both direct and indirect transmission routes. For direct transmission, the probability is based on the number of inhaled droplets. For indirect transmission via surfaces, the probability is based on the level of surface contamination and the frequency of contact.
The analytical model is validated against detailed droplet spreading simulations. Agent-based simulations are also performed to assess the relative impact of direct and indirect transmission in industrial settings with varying worker density and mobility.
The key findings are:
- Direct transmission from infected individuals is the dominant infection route, especially for high source rates like coughing.
- Indirect transmission via contaminated surfaces can also contribute significantly, especially in crowded industrial environments with shared workspaces.
- Reducing worker density and increasing disinfection of surfaces are important countermeasures to mitigate infection spread.
- There exists an optimal worker mobility level that balances the competing effects on infection transmission.
The analytical model provides a computationally efficient approach to assess infection risks in industrial settings, which can be integrated into automated protection ecosystems.
Statisztikák
The number of droplets released per second by an infected individual ranges from 1.5 to 66.
The half-life of droplets on surfaces ranges from 5 to 7 hours for common industrial materials.
The probability of infection from contact with a contaminated surface is approximately 1 in 10,000.
Idézetek
"The development of safety policies for protecting large groups of individuals working in indoor environments against disease spreading provides an important and challenging task."
"To address this issue, we investigate the scenario of workers getting infected by the dangerous airborne pathogen in a close to real-life industrial environment."
"From our results, we draft a set of countermeasures for infection spreading, which could be used as the basis of the prevention policy, suitable for use in industrial scenarios."