13.020.30 环境影响评定 标准查询与下载

KS C IEC TS 62933-5-1-2019 电能存储（EES）系统第5-1部分:电网集成EES系统的安全考虑通用规范

Electrical energy storage(EES) systems — Part 5-1: Safety considerations for grid-integrated EES systems — General specification

KS C IEC TS 62933-5-1:2019 电能存储（EES）系统第5-1部分:电网集成EES系统的安全考虑通用规范

Electrical energy storage(EES) systems — Part 5-1: Safety considerations for grid-integrated EES systems — General specification

KS C IEC TS 62933-4-1:2019 电能储存（EES）系统第4-1部分:环境问题指南通用规范

Electrical energy storage(EES) systems — Part 4-1: Guidance on environmental issues — General specification

KS C IEC 62933-2-1:2019 电能存储（EES）系统 第2-1部分:单元参数和测试方法 总规范

Electrical energy storage(EES) systems — Part 2-1: Unit parameters and testing methods — General specification

ASTM E3163-18 沉积物校正过程中分析方法和程序的选择和应用的标准指南

1.1 This is a guide for the selection and application of a range of analytical methods and testing procedures that may be used during sediment programs, including physical properties testing, chemical analytical methods, passive sampling procedures, bioassays and toxicity testing, environmental forensics methods and procedures, and methods development procedures for sediment programs. 1.2 Sediment programs vary greatly in terms of environmental complexity, physical, chemical and biological characteristics, human health and ecological risk concerns, and geographic and regulatory context. This guide provides information for the selection and application of analytical methods and testing protocols applicable to a wide range of sediment programs. 1.3 This guide describes widely accepted considerations and best practices used in the selection and application of analytical procedures used during sediment programs. This guide supports and complements existing regulations and technical guidance. 1.4 This guide is designed for general application to a wide range of sediment programs performed under international, federal, state and local environmental programs. This guide describes the selection and application of analytical methods and test procedures, not the requirements for specific regulatory jurisdictions. This guide compliments but does not replace regulatory agency requirements. 1.5 This guide may be used for a wide range of sediment programs, including programs with overlapping regulatory jurisdictions, programs without a clearly established regulatory framework, voluntary programs, Brownfield programs, and international programs. The users of this guide should be aware of the appropriate regulatory requirements that apply to sediment programs. The user should consult applicable regulatory agency requirements to identify appropriate technical decision criteria and seek regulatory approvals, as necessary, prior to 1 This guide is under the jurisdiction of ASTM Committee E50 on Environmental Assessment, Risk Management and Corrective Action and is the direct responsibility of Subcommittee E50.04 on Corrective Action. Current edition approved Sept. 1, 2018. Published November 2018. DOI: 10.1520/E3163–18 Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee. 1 selection and application of analytical methods and test procedures to sediment programs. 1.6 This guide supports the collaboration of stakeholders, including project sponsors, regulators, laboratory service providers, and others, on the selection and application of analytical procedures to sediment programs. This guide highlights key considerations for designing sediment program data acquisition plans, including applicability and use limitations of analytical methods and test procedures, and data usability considerations. This guide recognizes the challenges inherent in selection and application of analytical methods and test procedures for sediment systems, as well as the challenges inherent in generating analytical data of sufficient sensitivity to meet regulatory criteria applied to sediment programs. 1.7 ASTM standard guides are not regulations; they are consensus standard guides that may be followed voluntarily to support applicable regulatory requirements. 1.8 Test methods, procedures, and guidelines published by ASTM, USEPA, and other U.S. and international agencies are used for sediment programs, many of which are referenced by this guide. However, these documents do not provide guidance on the selection and application of analytical methods and test procedures for sediment programs. This guide was developed for that purpose. 1.9 This guide may be used in conjunction with other ASTM guides developed for sediment programs. 1.10 The user of this guide should review existing information and data available for a sediment project to determine the most appropriate entry point into and use of this guide. 1.11 Table of Contents: Section Introduction Scope 1 Referenced Documents 2 Terminology 3 Significance and Use 4 Physical Property Test Methods 5 Chemistry Analytical Methods 6 Passive Sampling Methods 7 Biological Test Methods 8 Environmental Forensics Analytical Methods 9 Analytical Method Development 10 Key Differences in Physical Properties of Sediment and Soil Appendix X1 Guidelines for Collection of Sediment Samples for Physical Properties Testing Appendix X2 Key Concepts in Sediment Stratigraphy for Physical Properties Testing Appendix X3 Quick Reference Guide for Sediment Chemistry Analytical Method Selection Appendix X4 Sampling Reference Guide for Sediment Chemistry Analytical Methods Appendix X5 Critical Success Factors for Sediment Chemistry Analytical Programs Appendix X6 Quick Reference Guide for Passive Sampling Method Selection Appendix X7 Advantages and Limitations of Passive Sampler Types for Organic Compounds Appendix X8 Methodologies and Equations for Determining Aqueous Chemical Concentrations from Passive Sampler Results Appendix X9 Pros and Cons Evaluation of Biological Test Methods Appendix X10 Decision Tree for Biological Testing Selection Appendix X11 Species List for Biological Testing Appendix X12 Section Daubert Criteria to Guide the Selection and Application of Analytical Test Methods Used for Environmental Sediment Forensics Appendix X13 References Bibliography 1.12 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.13 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

Standard Guide for Selection and Application of Analytical Methods and Procedures Used during Sediment Corrective Action

IEC TS 62933-3-1:2018 电能存储系统第3-1部分:电能存储系统的规划和性能评估通用规范

Electrical energy storage (EES) systems - Part 3-1: Planning and performance assessment of electrical energy storage systems - General specification

DB13/T 2745-2018 海洋溢油污染水产养殖损害评估技术指南

Technical Guidelines for Aquaculture Damage Assessment from Marine Oil Spill Pollution

ASTM E3136-18 水资源中气候弹性的标准指南

1.1 Overview—Water resources in North America and other areas are subject to various impacts from chronic weather patterns, as well as more frequent extreme weather events. These include drought, flooding, changes in stream patterns, increased or decreased run-off, and changes in water quality. Water resources include both man-made and natural reservoirs, rivers, streams, groundwater, and storage ponds. The infrastructure for water supply, wastewater treatment, fire-fighting and agricultural uses are also subject to chronic weather patterns and more frequent extreme weather related events. This guide will provide an explanation of techniques users may employ to build resiliency and a planning outline for municipalities, states and private industry in order to ensure safe, future, effective availability of water resources. 1.2 Purpose—The purpose of this guide is to provide a series of options that organizations may implement to prepare for the environmental impacts and risks from changing environmental conditions, chronic weather patterns, natural or man-made disasters, and extreme weather events. This guide also encourages consistent management of risks from natural disasters to water resources. The guide presents practices and recommendations based on regions and planning horizons that provide institutional and engineering actions to reduce the physical and financial vulnerabilities attributable to changing environmental conditions. It presents available technologies, institutional controls, and engineering controls that can be implemented by individuals and organizations seeking to increase their adaptive and resiliency capacity. 1.2.1 The guide also provides some high-level options for the planning, selection, implementation, and review of strategies in order to ensure that the approach continues to be environmentally responsible, in the best interest of the public, reasonable, and cost effective. This guide can be used to analyze the effectiveness of a community’s strategy. 1.2.2 This guide ties into the ASTM E50 standards series related to environmental risk assessment and management. 1.2.3 The guide does not provide risk assessment, per se, but may help set priorities for a climate resiliency program. 1.3 Safety—This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user to establish appropriate safety and health practices and determine the applicability of regulatory 1 This guide is under the jurisdiction of ASTM Committee E50 on Environmental Assessment, Risk Management and Corrective Action and is the direct responsibility of Subcommittee E50.05 on Environmental Risk Management. Current edition approved July 1, 2018. Published August 2018. DOI: 10.1520/ E3136–18 Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee. 1 limitations prior to use. Adaptation and resiliency measures, however, may be consistent with, and complementary to, safety measures. 1.4 Objectives—The objectives of this guide are to determine the conditions of the community, facility, and property with regard to risks of natural disaster events to water resources and actions that can be taken to manage those risks. 1.4.1 The guide presents information on planning and strategies to respond to extreme natural events such as drought, flood, storms and sea level rise upon water resources. 1.4.2 The guide encourages users to set priorities based upon the relevant region in the United States. For each region, the guide identifies key climate vulnerabilities that would require planning and preparation based on that particular scenario. These could be extrapolated to other regions if there are similar conditions. 1.4.3 The guide encourages the user to develop long term solutions for future risks. 1.5 Limitations of this Guide—Given the different types of organizations that may wish to use this Guide, as well as variations in state and local regulations, it is not possible to address all the relevant circumstances that might apply to a particular facility. This guide uses generalized language and examples for the user. If it is not clear to the user how to apply standards to their specific circumstances, users should seek assistance from qualified professionals. Risks may vary depending on the entity evaluating the risk. This guide does not take a position on the causes or science of extreme weather, natural disasters, or changing environmental conditions. 1.6 The guide uses references and information on the control, management and reduction of impacts from many cited sources. 1.7 Several national and international agencies served as sources of information on existing and anticipated levels and management of climate risks including: the Australian Ministry of Environment; the Federal Emergency Management Agency; the National Oceanographic and Atmospheric Administration; the Securities and Exchange Commission; the US Army Corps of Engineers; the US Department of Agriculture; the US Department of Energy; the US Environmental Protection Agency; and the US Department of Defense. 1.8 This guide recommends reference to current regulatory information about risks culled from various state agencies, such as departments of environmental protection and water resources boards. 1.9 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.10 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

Standard Guide for Climate Resiliency in Water Resources

EN IEC 62933-2-1:2018 电能存储（EES）系统 第 2-1 部分：单元参数和测试方法 通用规范

Electrical energy storage (EES) systems - Part 2-1: Unit parameters and testing methods - General specification

PD CEN/TS 15119-1:2018 木材和木制品的耐久性 防腐处理木材向环境排放的测定 第1部分：处理后存放在堆场的木材和暴露在使用类别 3 中的木制商品（未覆盖 未接触 wi

Durability of wood and wood-based products - Determination of emissions from preservative treated wood to the environment - Part 1: Wood held in the storage yard after treatment and wooden commodities exposed in Use Class 3 (not covered@ not in contact wi

MZ/T 106-2017 火葬场二噁英类污染物减排技术导则

Technical Guidelines for Reducing Emissions of Dioxin-Like Pollutants from Crematoriums

DB35/T 1725-2017 环境损害鉴定评估通用规范

本标准规定了环境损害鉴定评估的术语和定义、工作原则、通用程序、准备、勘查、鉴定及评估的方法和要求。 本标准适用于因污染环境或破坏生态行为（包括突发环境事件）导致人身、财产、生态环境损害、应急处置费用和其他事务性费用的鉴定评估。 本标准不适用于因核与辐射所致环境损害的鉴定评估。

General specification for environmental damage identification and assessment

IEC 62933-2-1:2017 电能存储（EES）系统 第2-1部分:单元参数和测试方法 总规范

This part of IEC 62933 focuses on unit parameters and testing methods of EES systems. The energy storage devices and technologies are outside the scope of this document. This document deals with EES system performance defining: unit parameters@ testing methods.

Electrical energy storage (EES) systems - Part 2-1: Unit parameters and testing methods - General specification

DB45/T 1625-2017 地质灾害危险性评估规程

Regulations on Risk Assessment of Geological Hazards

DB35/T 1692-2017 水利风景区评价标准

本标准规定了水利风景区评价的内容和方法。 本标准适用于福建省内现有及拟申报的省级、县级水利风景区的评价。

Evaluation Standards for Water Conservancy Scenic Spots

GSO IEC/TR 62725:2017 电气电子产品和系统温室气体排放量化方法分析

This Technical Report is intended to provide users with guidance to understand methodologies and to evaluate carbon footprint of products (hereinafter referred to as CFP), by quantifying the greenhouse gases (GHG) emissions (hereinafter referred to as CFP study) for Electrical and Electronic products (hereinafter referred to as EE products) based on life-cycle thinking. This TR is applicable to any type of EE products, which are new or modified (e.g. reconditioned, upgraded, etc.). This TR is based on the result of a comparative study on existing methodologies published or under discussion in representative international organizations. This TR is intended to be used by those involved in design and development of EE products, and their supply chains regardless of industry sectors, regions, types, activities and sizes of organizations. This TR may also be used as guidance to prepare a PCR of each product category in EE sector. NOTE 1 In this TR, ISO/DIS 14067, ITU-T L.1400 and L.1410, GHG Protocol Product Life Cycle Accounting and Reporting Standard (hereinafter referred to as (GHG Protocol Product Standard), BSI PAS 2050, and other international, regional and national initiatives are studied and compared since these documents and initiatives are regarded as the most influential ones worldwide at the moment. NOTE 2 This TR refers to requirements relevant to EE products in the existing documents and quotes them with boxes. The boxes are followed by guidance applicable to EE products. The documents which this TR refers to (e.g. ISO/DIS 14067) may be revised in the future. These boxes do not capture the full text of the standards referred to and readers are encouraged to read these standards for thorough understanding of their requirements. NOTE 3 This TR is programme-neutral. If a programme (e.g. a specific Carbon Footprint of Products (CFP) Initiative) is applicable, some requirements of that programme may be additional to the guidance provided in this TR.

Analysis of quantification methodologies of greenhouse gas emissions for electrical and electronic products and systems

GSO IEC/TR 62635:2017 制造商和回收商提供的报废信息以及电气和电子设备可回收率计算指南

IEC/TR 62635, which is a technical report, provides a methodology for information exchange involving EEE manufacturers and recyclers, and for calculating the recyclability and recoverability rates to • provide information to recyclers to enable appropriate and optimized EoL treatment operations, • provide sufficient information to characterize activities at EoL treatment facilities in order to enable manufacturers to implement effective ECD, • evaluate the recyclability and recoverability rates based on product attributes and reflecting real end-of-life practices. Furthermore this technical report includes: • criteria to describe EoL treatment scenarios; • criteria to determine product parts that might require removal before material separation and related information to be provided by manufacturers (location and material composition); • a format for information describing EoL scenarios and the results of EoL treatment activities; • a method for calculating the recyclability and recoverability rate of EEE. The calculation is limited to EoL treatment and does not cover collection. The recyclability rate is expressed as a percentage of the mass of the product that can be recycled or reused, whereas the recoverability rate in addition includes a portion derived from energy recovery. This techncial report can be applied to all electrical and electronic equipment; • some example data corresponding to identified scenarios provided in Annex D.

Guidelines for end-of-life information provided by manufacturers and recyclers and for recyclability rate calculation of electrical and electronic equipment

IEC TS 62933-4-1:2017 电能存储（EES）系统.第4-1部分:环境问题指南.一般规范

Electrical energy storage (EES) systems - Part 4-1: Guidance on environmental issues - General specification

IEC TS 62933-5-1:2017 电能存储（EES）系统第5-1部分:电网集成EES系统的安全考虑通用规范

Electrical energy storage (EES) systems - Part 5-1: Safety considerations for grid-integrated EES systems - General specification

GSO 2540:2017 石油天然气行业 项目环境影响评价

This document outlines the procedure necessary to prepare the required Environmental Screening and Scoping (ESS) Statements, included in the Design Basis Scoping Papers (DBSPs) for major capital projects, and in the expenditure requests for BI-19 Miscellaneous Capital Items. This document also outlines the procedure necessary to prepare the required Environmental Impact Assessments (EIAs) for major projects and for master appropriations (such as drilling operations) and BI-19 projects with a significant environmental impacts. The primary objective of both the ESS Statement and the EIA is to document the scope of environmental issues very early in the project in order to consider project alternatives that would reduce or eliminate adverse impacts and resource conservation potential. The EIA should recommend appropriate, cost-effective measures, which will mitigate significant environmental impacts, and describe how implementation of these recommendations will be monitored during construction and operation.

Petroleum and natural gas industries - Project Environmental Impact Assessments