Abstract
Environmental quality in public rail transit has recently raised great concern, with more attention paid to underground subway microenvironment. This research aimed to provide guidance for healthy urban subway microenvironments (sub-MEs) according to comprehensive micro-environmental categories, including thermal environment, air quality, lighting environment, and acoustic environment from both practical and regulation perspectives. Field sampling experiments were conducted in Nanjing Metro Line X (NMLX). Descriptive analysis, correlation analysis and one-way analysis of variance were used to investigate the status quo of urban sub-MEs. A paired samples t-test was then performed to compare among subway station halls, platforms, and in-cabin trains based on integrated sub-MEs. Results show that relative humidity, air velocity, respirable particulate matter (PM10) concentration, and illuminance dissatisfy the requirements in relevant national standards. Significant difference was observed in lighting environment between station hall and platform. It was detected platforms are warmer and more polluted than train cabins. Additionally, subway trains generate main noise on platform which is much louder when leaving than arriving. Protective strategies for sub-ME improvement as well as principles for updating standards were proposed from a proactive point of view. The findings are beneficial for moving towards healthy urban sub-MEs and more sustainable operation of subway systems.
Highlights
Public rail transit witnesses a remarkable leap forward with the rapid growth of urbanization in different countries/regions all over the world [1]
It is worth noticing that beyond-standard PM10 concentration simultaneously occurred in station halls as well as platforms of Yu Hua Men (YHM) station and West of Shengtai Road (WSTR) station
When compared with station halls and platforms, better subway microenvironments (sub-MEs) were recorded in cabins of carriages, where all ME-indicators measured conformed to the standard except Relative humidity (RH) (Mean = 70.2%, standard deviation (SD) = 0.7%) in their thermal environment (Table 3)
Summary
Public rail transit witnesses a remarkable leap forward with the rapid growth of urbanization in different countries/regions all over the world [1]. The underground subway, due to its efficiency, safety, and large-scaled passenger capacity, has gradually become one of the most prevalent commuting modes in rail transit systems [2,3]. According to the Statistics and Analysis Report of Urban Rail. Transit [4], the total passenger volume of rail transit nationwide had increased to 18.48 billion and. Res. Public Health 2019, 16, 625; doi:10.3390/ijerph16040625 www.mdpi.com/journal/ijerph
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