C67 工厂防火防爆安全技术 标准查询与下载

DIN EN 1839:2017-11 爆炸极限、燃烧气体和蒸汽极限氧含量(LOC)的测定;德文版本EN 1839-2017

Determination of the explosion limits and the limiting oxygen concentration (LOC) for flammable gases and vapours; German version EN 1839:2017

ISO/IEC 80079-20-2:2016/Cor 1:2017 爆炸性大气环境. 第20-2部分: 材料特性. 可燃尘埃试验方法; 技术勘误表1

Explosive atmospheres - Part 20-2: Material characteristics - Combustible dusts test methods; Technical Corrigendum 1

BS EN 1839:2017 爆炸极限、燃烧气体和蒸汽极限氧含量(LOC)的测定

Determination of the explosion limits and the limiting oxygen concentration (LOC) for flammable gases and vapours

DB32/T 2954-2016 液化天然气汽车箱式橇装加注设备安全技术规范

本标准规定了储罐几何容积不大于60m3的液化天然气汽车箱式橇装加注设备的加注设备术语、定义，安全、防火间距及结构型式，技术要求，调试，标志、出厂资料和运输，培训、使用、维护检修及事故应急处理。 本标准适用于储罐几何容积不大于60m3液化天然气汽车箱式橇装加注设备的设计、制造、安装、调试及使用。

Safety technical specifications for box-type skid-mounted filling equipment for liquefied natural gas vehicles

BS EN 60079-10-1:2015 爆炸性气体.第10-1部分:区域分级.爆炸性气体

Explosive atmospheres. Classification of areas. Explosive gas atmospheres

DB32/T 2914-2016 危险场所电气防爆安全检测作业规范

本标准规定了危险场所电气防爆安全检测作业的术语和定义、基本要求、检测项目及其要求、检测方法等。 本标准适用于安全生产检测检验机构对危险场所电气防爆安全检测及生产经营单位自检。

Operational Specifications for Electrical Explosion-proof Safety Testing in Hazardous Locations

ASTM D6890-16e1 用等容室内燃烧法测定柴油点火延迟和衍生十六烷值(DCN)的标准试验方法

5.1 The ID and DCN values determined by this test method can provide a measure of the ignition characteristics of diesel fuel oil in compression ignition engines. 5.2 This test can be used in commerce as a specification aid to relate or match fuels and engines. It can also be useful in research or when there is interest in the ignition delay of a diesel fuel under the conditions of this test method. 5.3 The relationship of diesel fuel oil DCN determinations to the performance of full-scale, variable-speed, variable-load diesel engines is not completely understood. 5.4 This test may be applied to non-conventional fuels. It is recognized that the performance of non-conventional fuels in full-scale engines is not completely understood. The user is therefore cautioned to investigate the suitability of ignition characteristic measurements for predicting performance in full-scale engines for these types of fuels. 5.5 This test determines ignition characteristics and requires a sample of approximately 100 mL and a test time of approximately 20 min on a fit-for-use instrument. 1.1 This automated laboratory test method covers the quantitative determination of the ignition characteristics of conventional diesel fuel oil, oil-sands based fuels, hydrocarbon oils, blends of fuel containing biodiesel material, diesel fuel oils containing cetane number improver additives, and is applicable to products typical of ASTM Specification D975 grades No. 1-D S15, No. 1-D S500, and No. 1-D S5000, and grades No. 2-D S15, No. 2-D S500, and No. 2-D S5000 diesel fuel oils, European standard EN 590, and Canadian standards CAN/CGSB-3.517 and 3.520. The test method may also be applied to the quantitative determination of the ignition characteristics of diesel fuel blending components. 1.2 This test method measures the ignition delay of a diesel fuel injected directly into a constant volume combustion chamber containing heated, compressed air. An equation correlates an ignition delay determination to cetane number by Test Method D613, resulting in a derived cetane number (DCN). 1.3 This test method covers the ignition delay range from 3.18201;ms8201;to 6.58201;ms (648201;DCN to 33 DCN). The combustion analyzer can measure shorter and longer ignition delays, but precision may be affected. For these shorter or longer ignition delays the correlation equation for DCN is given in Appendix X2. There is no information about how DCNs outside the 33 to 64 range compare to Test Method D613 cetane numbers. 1.4 For purposes of determining conformance with the parameters of this test method, an observed value or a calculated value shall be rounded “to the nearest unit” in the last right-hand digit used in expressing the parameter, in accordance with the rounding method of Practice E29.

Standard Test Method for Determination of Ignition Delay and Derived Cetane Number (DCN) of Diesel Fuel Oils by Combustion in a Constant Volume Chamber

ASTM E1529-16e1 测定钢构件和组件大型烃池防火效果的标准试验方法

5.1 These test methods are intended to provide a basis for evaluating the time period during which a beam, girder, column, or similar structural assembly, or a nonbearing wall, will continue to perform its intended function when subjected to a controlled, standardized fire exposure. 5.1.1 In particular, the selected standard exposure condition simulates the condition of total continuous engulfment of a member or assembly in the luminous flame (fire plume) area of a large free-burning-fluid-hydrocarbon pool fire. The standard fire exposure is basically defined in terms of the total flux incident on the test specimen together with appropriate temperature conditions. Quantitative measurements of the thermal exposure (total heat flux) are required during both furnace calibration and actual testing. 5.1.2 It is recognized that the thermodynamic properties of free-burning, hydrocarbon fluid pool fires have not been completely characterized and are variable depending on the size of the fire, the fuel, environmental factors (such as wind conditions), the physical relationship of the structural member to the exposing fire, and other factors. As a result, the exposure specified in these test methods is not necessarily representative of all the conditions that exist in large hydrocarbon pool fires. The specified standard exposure is based upon the best available information and testing technology. It provides a basis for comparing the relative performance of different assemblies under controlled conditions. 5.1.3 Any variation to construction or conditions (that is, size, method of assembly, and materials) from that of the tested assembly is capable of substantially changing the performance characteristics of the assembly. 5.2 Separate procedures are specified for testing column specimens with and without an applied superimposed load. 5.2.1 The procedures for testing loaded columns stipulate that the load shall be applied axially. The applied load is to be the maximum load condition allowed under nationally recognized structural design criteria unless limited design criteria are specified and a corresponding reduced load applied. 5.2.2 The procedure for testing unloaded steel column specimens includes temperature limits. These limits are intended to define the temperature above which a steel column with an axially applied design allowable load would fail structurally. 5.2.3 The procedure for unloaded specimens also provides for the testing of other than steel columns provided that appropriate acceptance criteria have been established. 5.3 Separate procedures are also specified for testing beam assemblies with and without an applied superimposed load. 5.3.1 The procedure for testing loaded specimens stipulates that the beam shall be simply supported. Application of restraint against longitudinal thermal expansion depends on the intended use, as specified by the customer. The applied load is intended to be the allowable design load p

Standard Test Methods for Determining Effects of Large Hydrocarbon Pool Fires on Structural Members and Assemblies

ASTM E1529-16 测定钢构件和组件大型烃池防火效果的标准试验方法

5.1 These test methods are intended to provide a basis for evaluating the time period during which a beam, girder, column, or similar structural assembly, or a nonbearing wall, will continue to perform its intended function when subjected to a controlled, standardized fire exposure. 5.1.1 In particular, the selected standard exposure condition simulates the condition of total continuous engulfment of a member or assembly in the luminous flame (fire plume) area of a large free-burning-fluid-hydrocarbon pool fire. The standard fire exposure is basically defined in terms of the total flux incident on the test specimen together with appropriate temperature conditions. Quantitative measurements of the thermal exposure (total heat flux) are required during both furnace calibration and actual testing. 5.1.2 It is recognized that the thermodynamic properties of free-burning, hydrocarbon fluid pool fires have not been completely characterized and are variable depending on the size of the fire, the fuel, environmental factors (such as wind conditions), the physical relationship of the structural member to the exposing fire, and other factors. As a result, the exposure specified in these test methods is not necessarily representative of all the conditions that exist in large hydrocarbon pool fires. The specified standard exposure is based upon the best available information and testing technology. It provides a basis for comparing the relative performance of different assemblies under controlled conditions. 5.1.3 Any variation to construction or conditions (that is, size, method of assembly, and materials) from that of the tested assembly is capable of substantially changing the performance characteristics of the assembly. 5.2 Separate procedures are specified for testing column specimens with and without an applied superimposed load. 5.2.1 The procedures for testing loaded columns stipulate that the load shall be applied axially. The applied load is to be the maximum load condition allowed under nationally recognized structural design criteria unless limited design criteria are specified and a corresponding reduced load applied. 5.2.2 The procedure for testing unloaded steel column specimens includes temperature limits. These limits are intended to define the temperature above which a steel column with an axially applied design allowable load would fail structurally. 5.2.3 The procedure for unloaded specimens also provides for the testing of other than steel columns provided that appropriate acceptance criteria have been established. 5.3 Separate procedures are also specified for testing beam assemblies with and without an applied superimposed load. 5.3.1 The procedure for testing loaded specimens stipulates that the beam shall be simply supported. Application of restraint against longitudinal thermal expansion depends on the intended use, as specified by the customer. The applied load is intended to be the allowable design load p

Standard Test Methods for Determining Effects of Large Hydrocarbon Pool Fires on Structural Members and Assemblies

IEC 60079-10-1:2015 爆炸性环境.第10-1部分:区域的分类.爆炸气体环境

This part of IEC 60079 is concerned with the classification of areas where flammable gas or vapour hazards may arise and may then be used as a basis to support the proper selection and installation of equipment for use in hazardous areas. It is intended to be applied where there may be an ignition hazard due to the presence of flammable gas or vapour, mixed with air, but it does not apply to: a) mines susceptible to firedamp; b) the processing and manufacture of explosives; c) catastrophic failures or rare malfunctions which are beyond the concept of abnormality dealt with in this standard (see 3.7.3 and 3.7.4); d) rooms used for medical purposes; e) commercial and industrial applications where only low pressure fuel gas is used for appliances e. g. for cooking, water heating and similar uses, where the installation is compliant with relevant gas codes; f) domestic premises; g) where a hazard may arise due to the presence of combustible dusts or combustible flyings but the principles may be used in assessment of a hybrid mixture (refer also IEC 60079-10-2). NOTE Additional guidance on hybrid mixtures is provided in Annex I. Flammable mists may form or be present at the same time as flammable vapour. In such case the strict application of the details in this standard may not be appropriate. Flammable mists may also form when liquids not considered to be a hazard due to the high flash point are released under pressure. In these cases the classifications and details given in this standard do not apply. Information on flammable mists is provided in Annex G. For the purpose of this standard, an area is a three-dimensional region or space. Atmospheric conditions include variations above and below reference levels of 101,3 kPa (1013 mbar) and 20 °C (293 K), provided that the variations have a negligible effect on the explosion properties of the flammable substances. In any process plant, irrespective of size, there may be numerous sources of ignition apart from those associated with equipment. Appropriate precautions will be necessary to ensure safety in this context. This standard is applicable with judgement for other ignition sources. This standard does not take into account the consequences of ignition of an explosive atmosphere.

Explosive atmospheres - Part 10-1: Classification of areas - Explosive gas atmospheres

EN 16647:2015 壁炉的液体燃料.装饰电器使用酒精或凝胶状燃料产生火焰.私人使用

This European Standard applies for decorative fireplaces/appliances for domestic use, producing a flame using alcohol, hereafter referred to as fuel, in liquid or gelatinous fuel for decoration. NOTE 1 The requirements are strictly applied even when used in other areas. Outside the private household and outdoor area can apply more or different rules on the use of the appliances. This European Standard applies to free-standing, wall-mounted and built-in appliances with a maximum power output of 4,5 kW. This European Standard applies for appliances ready for use, whose burner is of one unit or are an integral component of the appliances but not for appliances with a fuel tank separate from the appliance. This European Standard does not apply for appliances specifically designed for heating food or keeping food warm (rechauds), as well as for appliances for use in boats, caravans, other vehicles or outdoor areas. This European Standard does not apply for appliances with a power output higher than 4,5 kW or with a defined heating function. NOTE 2 National regulation may restrict the power output to less than 4,5 kW.

Fireplaces for liquid fuels - Decorative appliances producing a flame using alcohol based or gelatinous fuel - Use in private households

BS EN 60079-10-2:2015 爆炸性气氛 区域分类 爆炸性粉尘环境

Explosive atmospheres. Classification of areas. Explosive dust atmospheres

DB44/T 1540-2015 防爆场（厂）内专用机动车辆防爆安全性能检验规程

本标准规定了爆炸性环境用防爆场（厂）内专用机动车辆（以下简称“防爆车辆”）防爆性能的的检验一般要求、检验内容及要求。 本标准适用于爆炸性气体环境、可燃性粉尘环境用防爆车辆的防爆性能首次定期检验和定期检验。 本标准不适用于煤矿井下用车辆和炸药环境用车辆。

Inspection regulations for explosion-proof safety performance of special motor vehicles in explosion-proof field (factory)

AQ/T 3052-2015 危险化学品事故应急救援指挥导则

本标准规定了危险化学品事故应急救援指挥的基本原则和程序。 本标准适用于由政府部门、外部救援力量和事故单位共同参与救援的危险化学品事故的应急救援。

Guide for command of emergency rescue in hazardous chemical accidents

AQ 4241-2015 纺织工业除尘设备防爆技术规范

本标准规定了纺织工业粉尘爆炸危险场所用除尘设备的防爆要求。 本标准适用于纺织工业粉尘爆炸危险场所用除尘设备的设计、安装、使用与维护。

Technical specifications for dust explosion protection of dust removal equipment in textile industry

AQ/T 3054-2015 保护层分析（LOPA）方法应用导则

本标准规定了化工企业采用LOPA方法的技术要求，包括LOPA基本程序、场景识别与筛选、初始事件确认、独立保护层评估、场景频率技术、风险评估与决策、LOPA报告和LOPA后续跟踪及审查。 本标准适用于化工企业新建、改建、扩建和在役装置(设施)的保护层分析。

Guidelines for layer of protection analysis (LOPA)

GOST 31610.32-1-2015 爆炸性环境. 第32-1部分. 静电. 危害. 指南

Explosive atmospheres. Part 32-1. Electrostatic. Hazards. Guidance

GOST 31610.6-2015 爆炸性环境. 第6部分. 通过液体浸泡提供设备防护

Explosive atmospheres. Part 6. Equipment protection by liquid immersion «o»

BS EN 1127-2:2014 爆炸性环境.爆炸预防和防护.矿业用基本概念和方法

Explosive atmospheres. Explosion prevention and protection. Basic concepts and methodology for mining

DIN EN 60079-0:2014 爆炸性环境.第0部分:设备.通用要求(IEC 60079-0-2011, 修改件 + Cor. -2012+ Cor.-2013).德文版本EN 60079-0-2012+ A11-2013

Explosive atmospheres - Part 0: Equipment - General requirements (IEC 60079-0:2011, modified + Cor.:2012 + Cor.:2013); German version EN 60079-0:2012 + A11:2013