GB/T 38091.2-2019 English PDF

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GB/T 38091.2-2019: Nanotechnologies -- Occupational risk management applied to engineered nanomaterials -- Part 2: Use of the control banding approach
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Basic data

Standard ID: GB/T 38091.2-2019 (GB/T38091.2-2019)
Description (Translated English): Nanotechnologies -- Occupational risk management applied to engineered nanomaterials -- Part 2: Use of the control banding approach
Sector / Industry: National Standard (Recommended)
Classification of Chinese Standard: C52
Classification of International Standard: 07.030; 13.100
Word Count Estimation: 30,368
Date of Issue: 2019-10-18
Date of Implementation: 2020-05-01
Issuing agency(ies): State Administration for Market Regulation, China National Standardization Administration

GB/T 38091.2-2019: Nanotechnologies -- Occupational risk management applied to engineered nanomaterials -- Part 2: Use of the control banding approach

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Nanotechnologies--Occupational risk management applied to engineered nanomaterials--Part 2. Use of the control banding approach ICS 07.030; 13.100 C52 National Standards of People's Republic of China Occupational risk of nanotechnology engineering nanomaterials Management Part 2. Controlling the application of the classification method nanomaterials-Part 2.Useofthecontrolbandingapproach (ISO /T S12901-2..2014, IDT) Published on.2019-10-18 2020-05-01 implementation State market supervision and administration China National Standardization Administration issued

Content

Foreword I Introduction II 1 Scope 1 2 Normative references 1 3 Terms and Definitions 1 4 symbols and abbreviations 3 5 NOAA Control Grading Overall Framework 4 5.1 Overview 4 5.2 Information Collection and Data Recording 5 5.3 Hazard classification 5 5.4 Exposure rating 5 5.5 Control Rating 5 5.6 Review and data record 6 6 Information Collection 6 6.1 Hazard characterization 6 6.2 Exposure characterization 7 6.3 Control measures 8 7 Control rating 9 7.1 Overview 9 7.2 Hazard level determination 9 7.3 Exposure level determination 14 7.4 Control level determination and control strategy 17 7.5 Control Evaluation 17 7.6 Retrospective implementation method---risk rating 18 8 Implementation, inspection and continuous improvement 20 8.1 Overview 20 8.2 Objectives and implementation 20 8.3 Data record 20 8.4 Management Review 20 Appendix A (informative) Exposure algorithm in the Stoffenmanager risk grading method 21 Appendix B (informative) According to the health hazard category of GHS 23 Reference 24

Foreword

GB/T 38091 "Occupational Risk Management of Nanotechnology Engineering Nanomaterials" is divided into the following two parts. --- Part 1. Principles and methods; --- Part 2. Control the application of the classification method. This part is the second part of GB/T 38091. This part is drafted in accordance with the rules given in GB/T 1.1-2009. This section uses the translation method equivalent to ISO /T S12901-2.2014 "Nanotechnology Engineering Nanomaterials Occupational Risk Management Part 2. Controlling the application of classification methods. The documents of our country that have a consistent correspondence with the international documents referenced in this part are as follows. ---GB/T 32269-2015 Terms and definitions of nanotechnology nanoobjects Nanoparticles, nanofibers and nanosheets (ISO /T S27687.2008, IDT) This section has made the following editorial changes. --- Adjusted the order of the references. This part was proposed by the Chinese Academy of Sciences. This part is under the jurisdiction of the National Nanotechnology Standardization Technical Committee (SAC/TC279). This section drafted by. National Nanoscience Center, Beijing Labor Protection Science Research Institute, China Center for Disease Control and Prevention Health and Poison Control Institute, Zhejiang Provincial Center for Disease Control and Prevention. The main drafters of this section. Ge Guanglu, Guo Yuting, Tang Shichuan, Chang Bing, Zhang Meizhi, Xu Zhizhen.

Introduction

It is currently known that nano-objects and their aggregates and agglomerates larger than 100 nm (Nano-objects, andtheiraggregatesand Agglomeratesgreaterthan100nm, NOAA) exhibits properties different from non-nano-sized (bulk) materials, including toxicology nature. Since current Occupational Exposure Limits (OELs) are mostly based on bulk materials, they may not be suitable for NOAA. Jian In the absence of NOAA-related specifications, the control grading method can be used as the initial method to control NOAA exposure in the workplace. Note 1. Aggregates and agglomerates smaller than 100 nm are considered to be nano-objects. Controlled grading is a practical method for storms of potentially harmful substances with unknown or undetermined toxicological properties in the workplace. Dew control and lack of quantitative exposure assessment. If there are occupational exposure limits (OELs), refer to OELs, this method can be supplemented Traditional quantitative methods for air sampling and analysis. This method combines professional judgment and monitoring, and the occupational ring according to the similarity of hazard and exposure. Classification can provide an alternative risk assessment and risk management process. Based on the hazard and exposure range (grade), The program applies a range of control techniques (eg, full ventilation and containment) to specific chemicals. In general, control grading is based on the idea that people may be exposed to multiple chemicals, meaning that risks are diverse, but at risk The usual methods of control are limited. These risk control methods are divided into different levels ("strict") depending on the level of protection that can be provided. Control is the highest level of protection). The greater the potential for hazards, the higher the level of protection required for exposure control. Control grading was originally a safe working method developed by the pharmaceutical industry for new chemicals with little or no toxicity information. The method considers the exposure assessment status and classifies these new chemicals according to the toxicity of similar known chemicals, and pre-made The associated safe work procedures are associated. Thus each level corresponds to a corresponding control scheme [18]. According to this philosophy, British health and The safety management department has developed an easy-to-use procedure called COSHH [7][10][16], which mainly benefits the inability to obtain a specific occupational health. Small or medium-sized enterprises guided by biologists. Similar implementations were used in the implementation guidelines given by the German Federal Institute for Occupational Safety and Health. Procedure [5]. The Stoffenmanager tool [17] embodies a further development that combines a hazard grading procedure and base similar to COSHH. An exposure grading procedure for an exposure process model to facilitate understanding and use by non-professional users. Given the uncertainty of the potential health risk level of work-related NOAA, the risk rating of control grading for nanomaterials It is quite useful for evaluation and management. It can be managed in an active or retroactive manner for risk management. In an active implementation Existing control measures (if any) are not used as input variables for potential exposure grading, while in retrospective implementations, existing control measures As an input variable. Both methods are described in this section. Although control grading seems to be theoretically applicable to the storm of nanomaterials Dew control, but few comprehensive analytical tools are currently available for evolving nanotechnology operations. Maynard proposed a concept control The hierarchical model is given and the same four control methods as COSHH are given [15]. Paik et al. [20] [27] proposed a slightly different approach. The method is called "ControlBandingNanotool". This method takes into account NOAA's existing toxicological knowledge. The control grading framework proposed in the previous publications was applied. However, the range of values for controlling hierarchical nanotool applications is suitable for small scales. Study type operations (less than 1g) may not be suitable for large-scale production applications. At the same time, for controlling engineering in large-scale production applications Several specific control grading tools have been published for inhalation exposure of nanomaterials [6][12][13][14][23]. All of these tools define hazards Grades and inhalation exposure levels are combined into a two-dimensional matrix to derive risk control scores (active implementation). Schneider et al. [22] developed a conceptual model for the evaluation of inhalation exposure of engineered nanomaterials, presenting a model for future exposures. A general framework. This framework is used in conjunction with the Stoffenmanager tool and the AdvancedREACH tool (ART) [17][24][25] Inhalation exposes the same structure as the conceptual model. According to this conceptual model, they developed the "StoffenmanagerNano" control grader [26], which includes both active implementation and retrospective (risk grading) implementation. In addition, the French Food Environment and Occupational Health and Safety Agency (ANSES) has developed a control grading tool specifically for nanomaterials. The tool is described in a report entitled "Development of a specific control grading tool for nanomaterials" [11]. In the development of any NOAA control grading method, the biggest challenge is to decide which parameters need to be considered, a nano object corresponding A related criterion for controlling the grading method and what operational control strategy is employed at different operational levels. This section presents guidelines for controlling and managing occupational risks based on a control grading methodology designed specifically for NOAA. Manufacturing It is the responsibility of the business and importer to determine whether the material of interest contains NOAA in accordance with current national or international regulations and to provide safety data. Related information in the table (SDS) and labels. Companies can use this information to identify hazards and implement appropriate controls. This section is not intended to Providing advice for this decision-making process is not a substitute for rules and regulations, so companies must comply with current legal requirements. It is emphasized that the control grading method applied to engineering NOAA requires assumptions about difficult to obtain data. Therefore, control points Level tool users have reliable skills in chemical risk prevention, especially in material-related risk prevention. The success of this method Implementation requires the user's solid professional ability and critical evaluation of potential occupational exposure, as well as the use of control grading With to ensure that appropriate control measures and sufficiently rigorous methods are adopted. In addition to the methods described in this section, a comprehensive hazard assessment should consider all hazards associated with the substance, including the risk of explosion (see Note 2). And environmental hazards. Note 2. Most organic materials, many metals and even some non-metallic inorganic materials produce explosive dust clouds. Affects dust cloud ignition sensitivity and explosion The main factors of violentness are particle size or specific surface area (ie total surface area per unit volume or unit mass of dust) and particle composition. With the The particle size is reduced and its specific surface area is increased. At the same time, as the particle size decreases, the overall trend of dust explosion violent and flammability is increasing. of. Although the trend for many dusts is gradually stabilized when the particle size reaches the order of several tens of micrometers (μm), however, dust has not been established at present. There is no lower limit on the particle size of the explosion, so it is considered that many types of nanoparticles may cause an explosion. Occupational risk of nanotechnology engineering nanomaterials Management Part 2. Controlling the application of the classification method

1 Scope

This part of GB/T 38091 specifies the control grading method for occupational risk management of nanomaterials, which is applicable to both toxicity and quantification. Occupation of nano-objects and aggregates and agglomerates (NOAA) greater than 100 nm in the absence or lack of exposure assessment information The risks associated with exposure are controlled. The ultimate goal of controlling grading is to control exposure to prevent possible negative effects on human health. Control grader as described in this section For guidelines on inhalation control design, skin and eye protection, see ISO /T S12901-1 [2]. This section applies to man-made NOAA, including nanoparticles, nanopowders, nanofibers, nanotubes, nanowires, and their aggregation. Collective and agglomerate. In this section, the term "NOAA" refers to the initial state, or is doped in a material or reagent but in the week of use. The nano-components that can be released during the period. However, for many other industrial processes, nanotechnology processes may be inadvertently produced. As a by-product of the NOAA form, these possible health and safety issues are also of concern. This section provides an easy-to-understand practical way to control occupational exposure, designed to help businesses and other organizations, including manufacturing, plus Work or deal with NOAA research institutions. Control grading is applicable to occupational health related to the development, manufacture and use of NOAA under normal or substantially predictable conditions Problems, including maintenance and cleaning operations, but do not include accidental or accidental situations. Control grading is not intended to be used directly in the area of safety management, environment or transportation; it is only part of the overall risk control process. This section does not apply to biologically derived materials.

2 Normative references

The following documents are indispensable for the application of this document. For dated references, only dated versions apply to this article. Pieces. For undated references, the latest edition (including all amendments) applies to this document. ISO /T S27687 Terms and definitions for nanotechnology nanoobjects Nanoparticles, nanofibers and nanosheets (Nanotechn- ologies-Terminologyanddefinitionsfornano-objects-Nanoparticle,nanofibreandnanoplate)

3 Terms and definitions

The following terms and definitions defined by ISO /T S27687 apply to this document. For ease of use, the following is repeated Some terms and definitions in ISO /T S27687. 3.1 Agglomerate agglomerate A stack of weakly bound particles, an aggregate, or a mixture of the two, has an outer surface area that is similar to the sum of the surface areas of the individual particles. Note 1. The forces supporting the agglomerates are weak forces, such as van der Waals forces or simple physical entanglements. Note 2. Agglomerates are also referred to as secondary particles, while source particles are referred to as primary particles. [ISO /T S27687.2008, Definition 3.2] ......

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