Impact of air recirculation and humidification systems on wood dust exposure during woodworking.

IF 1.8 4区医学 Q3 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH

Annals Of Work Exposures and Health Pub Date : 2025-06-02 DOI:10.1093/annweh/wxaf027

Anne Straumfors, Ine Pedersen, Erika Zardin Brinchmann, Torunn Kringlen Ervik, Anani Afanou, Kristine H Anmarkrud, Monica Eidhammer, Oda A H Foss, Nils Petter Skaugset

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引用次数: 0

Abstract

Employees in the woodworking industry, including carpentry workshops, wood product factories, and the wooden house industry, are exposed to wood dust at work. In Norway, this industry is exempt from regulations banning air recirculation, intended to prevent harmful substance buildup in working environments. While wood dust exposure is linked to increased risks of cancer and respiratory diseases, eliminating the exemption could have significant economic consequences for companies reliant on heated air recirculation during winter. A detailed characterization of the exposure is needed to evaluate the health risks associated with recirculated air. Wood dust contains components like resin acids, endotoxins, fungi, bacteria, monoterpenes, and aldehydes, which can irritate the skin, eyes, and respiratory system. Understanding these exposures is crucial for evaluating whether existing occupational exposure limits (OELs) adequately protect workers' health. This study aimed to assess wood dust and associated exposures in companies with and without air recirculation or humidification. Between 2019 and 2023, full-shift personal aerosol sampling was conducted in 23 companies during winter. Samples were analyzed for wood dust mass, endotoxin, bacteria and fungi, resin acid, monoterpenes, and aldehydes. Log-transformed exposure data were analyzed by mixed models using company types and work-related conditions as fixed effects. Results showed average exposure below OELs but with significant variability. About 25% of measurements exceeded the OEL for inhalable wood dust of 1 mg/m3. Air recirculation had mixed effects; it lowered the monoterpene exposure by 95% (from GM 597 µg/m3 to GM 27 µg/m3) but increased the GM microbial exposure 2 to 5 times across companies. The impact of air recirculation varied across company types. For building element production, it nearly doubled the wood dust exposure from soft woods (from GM 0.15 mg/m3 to GM 0.27 mg/m3), while for door/window manufacturers, exposure was nearly halved compared to those not using air recirculation (from GM 0.44 mg/m3 to GM 0.25 mg/m3). Air humidification lowered the inhalable dust exposure by 59% across the company (from GM 1.36 mg/m3 to 0.56 mg/m3) but led to increases in monoterpene by 90 % (from GM 86 µg/m3 to GM 792 µg/m3) and microbial exposure by up to 64%. Companies manufacturing interior products without a humidification system had resin acid exposure levels that were 10 times higher (GM 3323 ng/m3) compared to those with a humidification system (GM 344 ng/m3). The variability in exposures was mostly influenced by company-specific practices. Evaluation of preventive measures should therefore be tailored to the individual company.

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空气再循环和加湿系统对木工过程中木屑暴露的影响。

木工行业的员工，包括木工车间、木制品工厂和木屋行业，在工作时都会接触到木材粉尘。在挪威，该行业不受禁止空气再循环的规定的约束，该规定旨在防止有害物质在工作环境中积聚。虽然木屑暴露与癌症和呼吸系统疾病的风险增加有关，但取消这一豁免可能会对那些在冬季依赖热空气再循环的公司产生重大经济后果。为了评估与再循环空气有关的健康风险，需要详细描述接触情况。木屑含有树脂酸、内毒素、真菌、细菌、单萜烯和醛等成分，这些成分会刺激皮肤、眼睛和呼吸系统。了解这些暴露对于评估现有的职业暴露限值（oel）是否足以保护工人的健康至关重要。本研究旨在评估木屑和相关的暴露在公司有和没有空气再循环或加湿。2019年至2023年期间，23家公司在冬季进行了全班个人气溶胶采样。对样品进行了木屑质量、内毒素、细菌和真菌、树脂酸、单萜烯和醛的分析。将公司类型和工作条件作为固定效应，采用混合模型对对数转换后的暴露数据进行分析。结果显示，平均暴露量低于OELs，但差异显著。约25%的测量结果超过了可吸入木屑1毫克/立方米的OEL。空气再循环的效果好坏参半；它降低了95%的单萜暴露量（从GM 597µg/m3降至GM 27µg/m3），但使各公司的转基因微生物暴露量增加了2至5倍。空气再循环的影响因公司类型而异。对于建筑构件生产，软木材的木屑暴露量几乎增加了一倍（从GM 0.15 mg/m3增加到GM 0.27 mg/m3），而对于门窗制造商来说，与不使用空气再循环的制造商相比，暴露量几乎减少了一半（从GM 0.44 mg/m3减少到GM 0.25 mg/m3）。空气加湿使整个公司的可吸入粉尘暴露量降低了59%（从GM 1.36 mg/m3降至0.56 mg/m3），但导致单萜烯增加了90%（从GM 86µg/m3降至GM 792µg/m3），微生物暴露量增加了64%。生产没有加湿系统的室内产品的公司的树脂酸暴露水平（GM 3323 ng/m3）比有加湿系统的公司（GM 344 ng/m3）高10倍。暴露的可变性主要受到公司具体做法的影响。因此，预防措施的评价应针对个别公司。

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来源期刊

Annals Of Work Exposures and Health Medicine-Public Health, Environmental and Occupational Health

CiteScore

4.60

自引率

19.20%

发文量

期刊介绍： About the Journal Annals of Work Exposures and Health is dedicated to presenting advances in exposure science supporting the recognition, quantification, and control of exposures at work, and epidemiological studies on their effects on human health and well-being. A key question we apply to submission is, "Is this paper going to help readers better understand, quantify, and control conditions at work that adversely or positively affect health and well-being?" We are interested in high quality scientific research addressing: the quantification of work exposures, including chemical, biological, physical, biomechanical, and psychosocial, and the elements of work organization giving rise to such exposures; the relationship between these exposures and the acute and chronic health consequences for those exposed and their families and communities; populations at special risk of work-related exposures including women, under-represented minorities, immigrants, and other vulnerable groups such as temporary, contingent and informal sector workers; the effectiveness of interventions addressing exposure and risk including production technologies, work process engineering, and personal protective systems; policies and management approaches to reduce risk and improve health and well-being among workers, their families or communities; methodologies and mechanisms that underlie the quantification and/or control of exposure and risk. There is heavy pressure on space in the journal, and the above interests mean that we do not usually publish papers that simply report local conditions without generalizable results. We are also unlikely to publish reports on human health and well-being without information on the work exposure characteristics giving rise to the effects. We particularly welcome contributions from scientists based in, or addressing conditions in, developing economies that fall within the above scope.