27.060.10 液体和固体燃料燃烧器 标准查询与下载

KS B 6208-2016 锅炉用玻璃量表

Gauge glasses for boilers

KS B 6208-2016(2021) 锅炉玻璃液位计

Gauge glasses for boilers

KS B 6034-2016 家用燃油热水器

Oil burning water heaters for domestic use

BS 5410-3:2016 燃油实施规程 炉, 窑, 烤箱, 燃油发电机和其他工业应用的安装

Code of practice for oil firing. Part 3: Installations for furnaces, kilns, ovens, oil-fuelled generators and other industrial purposes

ASTM D6448-16 废弃润滑油中提取工业燃烧器燃料的标准规格

1.1 This specification covers four grades of fuel oil made in whole or in part with hydrocarbon-based used or reprocessed lubricating oil or functional fluids, such as preservative and hydraulic fluids. The four grades of fuel are intended for use in various types of fuel-oil-burning industrial equipment under various climatic and operating conditions. These fuels are not intended for use in residential heaters, small commercial boilers, combustion engines, or marine applications, 1.1.1 Grades RFO4, RFO5L, RFO5H, and RFO6 are used lubricating oil blends, with or without distillate or residual fuel oil, or both, of increasing viscosity and are intended for use in industrial burners equipped to handle these types of recycled fuels. Note 1: For information on the significance of the terminology and test methods used in this specification, see Appendix X1. 1.2 This specification is for use in contracts for the purchase of fuel oils derived from used lubricating oil and for the guidance of consumers of such fuels. This specification does not address the frequency with which any particular test must be run. 1.3 Nothing in this specification shall preclude observance of national or local regulations, which can be more restrictive. In some jurisdictions, used oil is considered a hazardous waste and fuels from used oil are required to meet certain criteria before use as a fuel. Note 2: For United States federal requirements imposed on used oil generators, transporters and transfer facilities, reprocessors, marketers, and burners, see 40 CFR 279. Note 3: The generation and dissipation of static electricity can create problems in the handling of distillate burner fuel oils. For more information on the subject, see Guide D4865. 1.4 The values stated in SI units are to be regarded as standard; non-SI units, when given, are for information only.

Standard Specification for Industrial Burner Fuels from Used Lubricating Oils

DB13/T 2305-2015 蒸菌专用生物质燃料炉

Special biomass fuel stove for steaming bacteria

DB13/T 2314-2015 秸秆直燃锅炉

Straw direct fired boiler

KS B 8016-2015 燃具用点火变压器

Ignition transformers for burning appliances

KS B 6202-2015(2020) 铸铁锅炉的建设

Construction of cast iron boilers

KS B 6202-2015 铸铁锅炉的建造

Construction of cast iron boilers

NB/T 34026-2015 生物质颗粒燃料燃烧器

本标准规定了生物质颗粒燃料燃烧器的分类、要求、试验方法、检验规则、标识以及包装、运输和贮存。本标准适用于机械通风的生物质颗粒燃料燃烧器(简称燃烧器)的设计、制造和验收。

Biomass pellets burners

NB/T 34021-2015 生物质清洁炊事炉具

本标准规定了生物质清洁炊事炉具的型号表示方法、技术要求、安全要求、试验方法和检验规则等。本标准适用于带有烟囱的燃用生物质及其成型燃料的炊事炉具。

Clean biomass cookstove

ASTM D5986-96(2015) 测定含氧化合物、苯、甲苯、C8&x2013的标准试验方法；气相色谱/傅里叶变换红外光谱法测定成品汽油中的芳烃和总芳烃

Standard Test Method for Determination of Oxygenates, Benzene, Toluene, C8–C 12 Aromatics and Total Aromatics in Finished Gasoline by Gas Chromatography/Fourier Transform

KS B 8901-2015 木屑颗粒锅炉

Wood pellet boilers

ASTM D6615-15 喷射B类宽馏分航空涡轮机燃料的标准规格

1.1 This specification covers the use of purchasing agencies in formulating specifications for purchases of aviation turbine fuel under contract. 1.2 This specification defines one specific type of aviation turbine fuel for civil use. This fuel has advantages for operations in very low temperature environments compared with other fuels described in Specification D1655. This fuel is intended for use in aircraft that are certified to use such fuel. 1.3 This specification does not define the quality assurance testing and procedures necessary to ensure that fuel in the distribution system continues to comply with this specification after batch certification. Such procedures are defined elsewhere, for example in ICAO8201;9977, EI/JIG Standard8201;1530, JIG8201;1, JIG8201;2, API8201;1543, API8201;1595, and ATA-103.

Standard Specification for Jet B Wide-Cut Aviation Turbine Fuel

ASTM D6550-15 采用超临界流体色谱法测定汽油中链烯含量的标准试验方法

5.1 Gasoline-range olefinic hydrocarbons have been demonstrated to contribute to photochemical reactions in the atmosphere, which result in the formation of photochemical smog in susceptible urban areas. 5.2 The California Air Resources Board (CARB) has specified a maximum allowable limit of total olefins in motor gasoline. This necessitates an appropriate analytical test method for determination of total olefins to be used both by regulators and producers. 5.3 This test method compares favorably with Test Method D1319 (FIA) for the determination of total olefins in motor gasolines. It does not require any sample preparation, has a comparatively short analysis time of about 10 min, and is readily automated. Alternative methods for determination of olefins in gasoline include Test Methods D6839 and D6296. 1.1 This test method covers the determination of the total amount of olefins in blended motor gasolines and gasoline blending stocks by supercritical-fluid chromatography (SFC). Results are expressed in terms of mass % olefins. The application range is from 18201;mass8201;% to 258201;mass % total olefins. 1.2 This test method can be used for analysis of commercial gasolines, including those containing varying levels of oxygenates, such as methyl tert/butyl ether (MTBE), diisopropyl ether (DIPE), methyl tert/amyl ether (TAME), and ethanol, without interference. Note 1: This test method has not been designed for the determination of the total amounts of saturates, aromatics, and oxygenates. 1.3 This test method includes a relative bias section based on Practice D6708 accuracy assessment between Test Method D6550 and Test Method D1319 for total olefins in spark-ignition engine fuels as a possible Test Method D6550 alternative to Test Method D1319 for U.S. EPA regulations reporting. The Practice D6708 derived correlation equation is only applicable for fuels in the concentration range from 0.2 % to 26.2 % by mass as reported by Test Method D6550. The applicable Test Method D1319 concentration range for total olefins is 0.2 % to 27.7 % by volume as reported by Test Method D1319. 1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.5 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 sta......

Standard Test Method for Determination of Olefin Content of Gasolines by Supercritical-Fluid Chromatography

ASTM E2154-15a 通过用固相微萃取 (SPME) 的被动顶部空间浓缩法从火的残留物中分离和浓缩可燃液体残渣的标准实施规程

4.1 This practice is suited ideally for screening samples for the presence, relative concentration, and potential class of ignitable liquid residues in fire debris. 4.2 This is a very sensitive separation procedure, capable of isolating small quantities of ignitable liquid residues from a sample, that is, a 0.1 μL spike of gasoline on a cellulose wipe inside of a 1-gal can is detectable. 4.3 Actual recovery will vary, depending on several factors, including adsorption temperature, container size, competition from the sample matrix, ignitable liquid class and relative ignitable liquid concentration. 4.4 Because this separation takes place in a closed container, the sample remains in approximately the same condition in which it was submitted. Repeat and interlaboratory analyses, therefore, may be possible. Since the extraction is nonexhaustive, the technique permits reanalysis of samples. 4.5 This practice is intended for use in conjunction with other extraction techniques described in Practices E1386, E1388, E1412, and E1413. 4.6 The extract is consumed in the analysis. If a more permanent extract is desired, one of the separation practices described in Practices E1386, E1412, or E1413 should be used. 1.1 This practice describes the procedure for removing small quantities of ignitable liquid residues from samples of fire debris. An adsorbent material is used to extract the residue from the static headspace above the sample. Then, analytes are thermally desorbed in the injection port of the gas chromatograph (GC). 1.2 This practice is best suited for screening fire debris samples to assess relative ignitable liquid concentration and for extracting ignitable liquid from aqueous samples. 1.3 This practice is suitable for extracting ignitable liquid residues when a high level of sensitivity is required due to a very low concentration of ignitable liquid residues in the sample. 1.3.1 Unlike other methods of separation and concentration, this method recovers a minimal amount of the ignitable residues present in the evidence, leaving residues that are suitable for subsequent resampling. 1.4 Alternate separation and concentration procedures are listed in Section 2. 1.5 This standard cannot replace knowledge, skill, or ability acquired through appropriate education, training, and experience and should be used in conjunction with sound professional judgment.

Standard Practice for Separation and Concentration of Ignitable Liquid Residues from Fire Debris Samples by Passive Headspace Concentration with Solid Phase Microextraction (SPME)

ASTM E2154-15 采用带有固相微量萃取 (SPME) 的无源顶部空间浓缩法对燃烧残骸试样中可燃性液体残留物进行分离和浓缩的标准实践规程

4.1 This practice is suited ideally for screening samples for the presence, relative concentration, and potential class of ignitable liquid residues in fire debris. 4.2 This is a very sensitive separation procedure, capable of isolating small quantities of ignitable liquid residues from a sample, that is, a 0.1 μL spike of gasoline on a cellulose wipe inside of a 1-gal can is detectable. 4.3 Actual recovery will vary, depending on several factors, including adsorption temperature, container size, competition from the sample matrix, ignitable liquid class and relative ignitable liquid concentration. 4.4 Because this separation takes place in a closed container, the sample remains in approximately the same condition in which it was submitted. Repeat and interlaboratory analyses, therefore, may be possible. Since the extraction is nonexhaustive, the technique permits reanalysis of samples. 4.5 This practice is intended for use in conjunction with other extraction techniques described in Practices E1386, E1388, E1412, and E1413. 4.6 The extract is consumed in the analysis. If a more permanent extract is desired, one of the separation practices described in Practices E1386, E1412, or E1413 should be used. 1.1 This practice describes the procedure for removing small quantities of ignitable liquid residues from samples of fire debris. An adsorbent material is used to extract the residue from the static headspace above the sample. Then, analytes are thermally desorbed in the injection port of the gas chromatograph (GC). 1.2 This practice is best suited for screening fire debris samples to assess relative ignitable liquid concentration and for extracting ignitable liquid from aqueous samples. 1.3 This practice is suitable for extracting ignitable liquid residues when a high level of sensitivity is required due to a very low concentration of ignitable liquid residues in the sample. 1.3.1 Unlike other methods of separation and concentration, this method recovers a minimal amount of the ignitable residues present in the evidence, leaving residues that are suitable for subsequent resampling. 1.4 Alternate separation and concentration procedures are listed in Section 2. 1.5 This standard cannot replace knowledge, skill, or ability acquired through appropriate education, training, and experience and should be used in conjunction with sound professional judgment.

Standard Practice for Separation and Concentration of Ignitable Liquid Residues from Fire Debris Samples by Passive Headspace Concentration with Solid Phase Microextraction (SPME)

ASTM D6615-15a 喷射B类宽馏分航空涡轮机燃料的标准规格

1.1 This specification covers the use of purchasing agencies in formulating specifications for purchases of aviation turbine fuel under contract. 1.2 This specification defines one specific type of aviation turbine fuel for civil use. This fuel has advantages for operations in very low temperature environments compared with other fuels described in Specification D1655. This fuel is intended for use in aircraft that are certified to use such fuel. 1.3 This specification does not define the quality assurance testing and procedures necessary to ensure that fuel in the distribution system continues to comply with this specification after batch certification. Such procedures are defined elsewhere, for example in ICAO8201;9977, EI/JIG Standard8201;1530, JIG8201;1, JIG8201;2, API8201;1543, API8201;1595, and ATA-103.

Standard Specification for Jet B Wide-Cut Aviation Turbine Fuel

BS 5410-1:2014 燃油规范.第1部分:输出功率小于等于45KW的环流供暖及热水供应锅炉装置

This part of BS 5410 gives recommendations and guidance on the design,installation,commissioning and maintenance of oil burning installations up to 45 kW output capacity for space heating and hot water supply purposes. It also gives recommendations and guidance on the selection and installation of oil tanks of capacity up to 3 500 L,when installed at buildings used primarily as dwellings. The standard is also applicable to oil fired cookers where these are connected to flues. This part of BS 5410 is not applicable to oil fired systems for marine and transportable installations,or for flueless heaters. This part of BS 5410 is applicable to installations burning liquid fuel conforming to BS 2869:2010+A1,including biofuels conforming to BS EN 14214,and blends thereof. This standard is intended for use by designers,specifiers,installers,and service and commissioning engineers.

Code of practice for oil firing. Installations up to 45 kW output capacity for space heating and hot water supply purposes