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measurement science and technology模板Title: Measurement Science and Technology: Advancing Accuracy and Precision in Scientific Measurements1. Introduction- Definition of Measurement Science and Technology and its significance in various scientific fields.- Brief overview of the importance of accurate and precise measurements in scientific research and technological advancements.2. Principles of Measurement Science- Description of the fundamental principles behind measurement science, including traceability, calibration, uncertainty, and metrology.- Explanation of how these principles enable the establishment of reliable and comparable measurements.3. Instrumentation and Measurement Techniques- Overview of the different measurement tools and instruments used in measurement science and technology, such as sensors, probes, and detectors.- Explanation of various measurement techniques employed, including spectroscopy, chromatography, microscopy, etc.4. Metrology and Standards- Detailed discussion on the role of metrology in measurement science and technology, including the establishment and maintenance of measurement standards.- Explanation of how standards are crucial for ensuring accuracy,comparability, and traceability of measurements.5. Measurement Uncertainty- Explanation of measurement uncertainty and its significance in measurement science and technology.- Discussion of different sources of uncertainty, such as systematic and random errors, and their impact on measurement accuracy. 6. Advances in Measurement Science and Technology- Overview of recent advancements and innovations in measurement science and technology, such as nanoscale measurements, quantum metrology, and remote sensing.- Discussion on how these advancements contribute to improving measurement accuracy, precision, and sensitivity.7. Applications of Measurement Science and Technology- Description of the diverse applications of measurement science and technology in various fields, including physics, chemistry, biology, medicine, engineering, environmental sciences, and manufacturing.- Examples of how accurate and precise measurements have led to significant scientific discoveries and technological advancements.8. Challenges and Future Directions- Discussion on the challenges faced in measurement science and technology, including novel measurement needs, standardization issues, and emerging measurement areas.- Exploration of future directions and potential solutions for addressing these challenges, such as advancements in data analysis techniques and the use of artificial intelligence in measurements.9. Conclusion- Recap of the importance of measurement science and technology in scientific research and technological advancements.- Emphasis on the continuous need for accurate and precise measurements to drive innovation and progress in various fields.。
en343 透气标准-回复En343 is a standard that governs the breathability of protective clothing. In this article, I will delve into the different aspects of the standard and explain its significance in ensuring comfort and safety for wearers.The En343 standard, titled "Protective clothing - Protection against rain," was developed by the European Committee for Standardization (CEN). It specifies two parameters for breathability –water vapor resistance and water penetration resistance. These criteria are crucial in determining the functionality of protective clothing in various weather conditions.Water vapor resistance measures the ability of the fabric to allow moisture to escape from the body. It is determined by the measurement of the Resistance to Evaporative Heat Transfer (RET) value. A lower RET value indicates higher breathability, meaning that the fabric allows moisture to escape more easily. The EN343 standard specifies different classes for water vapor resistance, ranging from Class 1 (RET < 20) to Class 3 (RET > 40).Water penetration resistance, on the other hand, measures theability of the fabric to prevent water from penetrating through the material. This parameter is crucial, especially for garments intended to protect wearers from rain or wet environments. It is determined by the measurement of the Water Resistance (WR) value. TheEN343 standard also specifies different classes for water penetration resistance, ranging from Class 1 (WR 8000) to Class 3 (WR 10000).To meet the En343 standard, manufacturers must subject their protective clothing to rigorous testing in accredited laboratories. These tests involve exposing the fabric to artificial rain, simulating different levels of rainfall intensity. The clothing's water penetration resistance is evaluated by measuring the amount of water that can penetrate the fabric after a specific period of time. Similarly, the water vapor resistance is determined by evaluating the RET value using a sweating thermal manikin or a specific test apparatus.The significance of the En343 standard lies in ensuring the comfort and safety of wearers. Protective clothing with high breathability allows moisture to escape, preventing the buildup of sweat and maintaining a comfortable microclimate inside the garment. This is particularly important for workers engaged in physicallydemanding activities or in challenging weather conditions. When moisture accumulates inside the garment, it can lead to discomfort, reduced mobility, and even the risk of hypothermia in cold environments.Moreover, if protective clothing does not meet the En343 standard's water penetration resistance criteria, it can fail to protect wearers from rain or wet environments. Water ingress can lead to wetness, thereby compromising the thermal insulation properties of the clothing and increasing the risk of cooling down the body. Additionally, wet clothing can lead to chafing, discomfort, and even skin irritation.The En343 standard is not only applicable to professional workwear but also to outdoor clothing for recreational activities. Whether it is hiking, mountaineering, or any other outdoor sport, clothing that meets the En343 standard ensures that wearers stay dry and comfortable, even in adverse weather conditions.While the En343 standard is essential in determining the breathability of protective clothing, it is important to note that it is just one aspect of a comprehensive evaluation of performance andsuitability. Other factors such as durability, flexibility, and compatibility with other protective equipment should also be considered.In conclusion, the En343 standard plays a vital role in determining the breathability of protective clothing. By specifying criteria for both water vapor resistance and water penetration resistance, it ensures that the clothing offers comfort and protection in various weather conditions. Manufacturers and consumers alike must prioritize this standard to obtain high-quality protective clothing that meets the necessary performance requirements.。
The fundamentals of microelectronics refer to the basic principles and concepts that form the foundation of the field. Microelectronics deals with the study and application of small-scale electronic components, such as integrated circuits and transistors. This field has played a crucial role in the development of various technologies, including computers, smartphones, and medical devices.One of the key concepts in microelectronics is the idea of miniaturization. Microelectronic components are designed to be small and compact, allowing for increased functionality in a limited space. This miniaturization is made possible by advancements in semiconductor technology, which enables the production of smaller and more efficient electronic devices.Another fundamental principle is the understanding of electronic circuits. Microelectronics relies on the design and analysis of circuits that control the flow of electric current. These circuits can be composed of different components, such as resistors, capacitors, and inductors, which work together to perform specific tasks.The behavior of microelectronic devices is guided by the laws of physics, particularly quantum mechanics. At the nanoscale level, where microelectronics operates, particles exhibit quantum effects that can significantly impact the performance of electronic devices. Understanding these effects is essential for designing and optimizing microelectronic components.In addition to the physical principles, microelectronics also encompasses the study of fabrication techniques. The process of manufacturing microelectronic devices involves multiple steps, including deposition, lithography, etching, and doping. Each of these steps contributes to the creation of complex integrated circuits and other microelectronic components.The field of microelectronics also includes the study of electronic materials. Different materials exhibit unique properties that can be leveraged in microelectronic devices. For example, semiconductors, such as silicon, are widely used in microelectronics due to their ability to control the flow of electric current.Overall, the fundamentals of microelectronics cover a wide range of topics, including circuit design, semiconductor physics, fabrication techniques, and electronic materials. Understanding these principles is crucial for the development of new and innovative microelectronic devices that drive technological advancements in various industries.。
冠层孔隙度的英文简称Canopy porosity (CP): The canopy's three-dimensional space occupied by air relative to the total space occupied by both air and leaves.Introduction.Canopy porosity (CP) is a critical structural attribute of forest canopies that significantly influences various ecological processes, including light penetration, canopy microclimate, and animal movement. It is defined as the fraction of canopy space occupied by air relative to the total space occupied by both air and leaves. CP plays a crucial role in determining the amount of solar radiation reaching the forest floor, influencing plant growth, understory development, and forest regeneration dynamics.Methods for Measuring CP.Several methods have been developed to measure CP, eachwith its advantages and limitations:1. Direct Measurement: This method involves physically measuring the canopy's volume and the volume of air it contains. It provides accurate results but can be time-consuming and difficult to implement for large or complex canopies.2. Optical Methods: These methods utilize sensors to measure the amount of light transmitted through the canopy. CP is estimated based on the assumption that light attenuation is directly related to the amount of leaf area present. Optical methods are relatively quick and non-destructive but can be affected by factors such as leaf angle and illumination conditions.3. Modeling Approaches: CP can also be estimated using mathematical models that simulate canopy structure andlight penetration. These models require detailed information about leaf size, shape, and distribution within the canopy. Modeling approaches provide valuable insights but can be sensitive to the accuracy of input parameters.Factors Influencing CP.CP is influenced by various factors, including:1. Leaf Area Index (LAI): LAI represents the total leaf area per unit ground area and is positively correlated with CP. Higher LAI generally leads to lower CP due to increased leaf overlap and shading.2. Leaf Size and Shape: Larger leaves tend to reduce CP more than smaller leaves due to their greater surface area and ability to overlap. Leaf shapes also influence CP, with complex or dissected leaves creating more gaps and higher porosity than simple or entire leaves.3. Crown Architecture: The arrangement of branches and leaves within a tree crown affects CP. Trees with dense, compact crowns have lower porosity than those with open, spreading crowns.4. Species Composition: Different tree species havedistinct leaf characteristics and crown architectures that influence CP. Mixed-species stands generally have higher CP than monocultures due to variations in leaf size, shape, and crown structure among species.Ecological Significance of CP.CP has significant ecological implications, including:1. Light Availability: CP regulates the amount of sunlight reaching the forest floor, affecting plant growth and understory development. Higher CP allows more light to penetrate the canopy, promoting understory vegetation and increasing forest productivity.2. Microclimate: CP influences the canopy microclimate by affecting temperature, humidity, and wind speed. Dense canopies with low CP tend to have cooler and more humid microclimates, while open canopies with high CP experience greater temperature fluctuations and wind penetration.3. Animal Movement: CP facilitates animal movementthrough the canopy. Animals can navigate more easily through canopies with high CP due to reduced physical barriers and increased visibility. This is particularly important for arboreal animals and birds that rely on the canopy for shelter and foraging.Conclusion.Canopy porosity is a vital structural attribute of forest canopies that plays a critical role in ecological processes. It influences light penetration, canopy microclimate, and animal movement, affecting the overall functioning and biodiversity of forest ecosystems. Understanding and quantifying CP is essential for developing sustainable forest management practices and conserving the ecological integrity of forests.。
地理专业词汇英语翻译(50)地理专业词汇英语翻译(50)地理专业词汇英语翻译(50)metamorphic diffusion 变质扩散metamorphic facies series 变质相系metamorphic ore deposit 变质矿床metamorphic rock 变质岩metamorphic schists 变质片岩metamorphism 变质酌metamorphogenic deposits 变质矿床metamorphosis 变态metasomatic deposit 交代矿床metasomatism 交代酌metasome 交代矿物metastable state 亚稳状态metazoa 后生动物meteor 燎meteor crater 陨石坑meteoric dust 燎埃meteoric water 天落水meteorite 陨石meteorograph 气象计;气象记录仪meteoroid 宇宙尘meteorological acoustics 气象声学meteorological chart 气象图meteorological element 气象要素meteorological information 气象情报meteorological insturment 气象仪器meteorological message 天气报告meteorological observation 气象观测meteorological observational tower 气球观测塔meteorological observatory 气象台meteorological optical range 气象光学距离meteorological optics 气象光学meteorological phenomenon 气象现象meteorological radar 气象雷达meteorological rocket 气象火箭meteorological satellite 气象卫星meteorological thermodynamics 气象热力学meteorological tide 气象潮meteorological visibility range 气象能见距离meteorology 气象学meteorotropism 气候铅性methane bacteria 甲烷细菌method 方法method of analogue 类比法method of angle observation in all combination 全组合测角法method of areas 面积法method of cartographic representation 地图表示法method of cartographic symbols 地图符号法method of direct coordinate 直角坐标法method of direct observation 直接观测法method of direction observation in rounds 全圆测回法method of indirect observation 间接观测法method of induction 归纳法method of iteration 迭代法method of least squares 最小二乘法method of measurement 测量方法method of neutron activation 中子话化法method of polar coordinates 极坐标法method of representation by means of cartographic symbols 地图符号法method of successive corrections 逐渐改正法methyl violet 甲基紫metrophotography 摄影测量学mica schist 云母片岩micaceous iron ore 云母铁矿micagneiss 云母片麻岩micelle 胶束micrinite 碎片体micro altimeter 微高度计micro nutrient 微量营养元素microanalysis 微量分析microanalyzer 微量分析器microanemometer 微风速器microbalance 微量天平microbarograph 自记微气压计microbe 微生物microbial oxidation 微生物氧化microbial prospecting 微生物勘探microbiological anomaly 微生物异常microbiology 微生物学microchemical analysis 微量化学分析microcinematography 显微电影术microclimate 小气候microclimate of mire 沼泽小气候microclimatology 小气候学microcline 微斜长石microcrystalline structure 微晶型结构microcrystalline texture 微晶质结构microdensitometer 侧微密度计microdensitometry 微密度测定microelement 痕量元素microenvironment 微环境microevolution 微进化microfauna 微动物区系microfissure 微裂隙microflora 微生物群落microfossils 微体化石microgeography 微观地理学microgeomorphology 微地貌学microgranite 微花岗岩microhabitat 小环境microhydrology 微水文学microlite 微晶microlithotype of coal 显微煤岩类型micromanipulation 显微操作micrometeorograph 微气象记录仪micrometeorology 微气象学micrometer 测微计micrometer microscope 测微显微镜micrometer value 测微浦划值microoceanography 微海洋学microorganism 微生物micropaleontological method 微体古生物法micropaleontology 微古生物学micropedology 微土壤学microphylly 小叶microphysiography 显微地文学microplankton 小型浮游生物microplate 微板块micropluviometer 微雨量计micropolarimeter 测微偏振计micropopulation 微生物群microporosity 微孔隙度microprocessor 微处理机microradiography 显微射线照相术microradiometer 显微辐射计microrelief 小地形microscope 显微镜microscopic analysis 显微分析microscopic theodolite 读数显微镜经纬仪microscopy 显微镜检查microsection 薄片microseismic movement 微震microseismic region 微震区microseisms 微震microskeleton 微骨架microsome 微粒体microspectrophotometry 微量分光光度测定法microsporangium 小孢子囊microspore 小孢子microstructure 微结构microtherm 低温植物microtome 切片机microtopography 微地形学;小地貌microwave altimeter 微波测高计microwave hologram radar 微波全息雷达microwave holography 微波全息microwave image 微波影像microwave radar image matching guidance 微波雷达图像匹配制导microwave radiation from sea surface 海面微波辐射microwave radiometer 微波辐射计microwave remote sensing 微波遥感microwave scattering 微波散射microwave sounding 微波测深microwave spectrometer 微波频谱仪地理专业词汇英语翻译(50) 相关内容:。
msa 计量型计数型英语The MSA (Measurement, Selection, and Analysis) method is a type of statistical analysis that focuses on measuring and analyzing data to make decisions. This method is commonly used in research and business to determine the effectiveness of a particular process or to identify trends and patterns in data. MSA involves the use of various statistical tools and techniques to quantify and evaluate the variability and accuracy of measurements.On the other hand, the Counting method is a type of statistical analysis that focuses on the frequency of occurrences of specific events or items within a given data set. This method is often used to track the number of defects, errors, or occurrences of a particular eventwithin a process. Counting methods can help identify areas for improvement and track the progress of process changes over time.In English:MSA (Measurement, Selection, and Analysis)方法是一种统计分析方法,其重点是测量和分析数据以做出决策。
地理词汇英语翻译(F开头) fabric 构造fabric diagram 组构图fabric domain 组构域fabric element 组构要素fabric unit 组构要素facetted pebble 棱石facetted peneplain 交叉准平原facetted spur 截切山嘴facies analysis 相分析facies change 相变facies fossil 指相化石facies index 指相化石factor 因素factor analysis 因数分析factor combination 因子组合factor matrix 因子矩阵factor model 因子模型factor of adhesion 粘着系数factorial experiment 因子试验facultative anaerobe 兼性嫌气生物fading 褪色faint negative 弱反差底片fair copy 出版原图fair drafting 出版原图fair draught 清绘原图fair sheet 海测原图fair wind 顺风fall line 瀑布线fall wind 下降风falling ball viscosimeter 落球粘度计falling tide 落潮fallow land 休地fallow soils 休闲土壤false anomaly 假异常false bedding 交错层false cirrus 伪卷云false cleavage 假劈理false color composite 假彩色合成false color film 假彩色胶片false colour composite image 假彩色合成影像false origin 假定原点false terrace 假阶地family 科fan fold 扇状褶皱fanglomerate 扇积砾fango 治疗矿泥far infrared 远红外线far infrared radiation 远红外辐射far point 远点far ultraviolet 远紫外线far ultraviolet radiation 远紫外辐射farm soil 耕琢farm water requirement 田间需水量farmland 农田farmland evaluation 农田评价farmyard manure 厩肥fascioliasis 片吸虫病fast fourier transform 快速傅里叶变换fast ice 固定冰fat coal 肥煤fat soil 肥土fathogram 测深图fatigue 疲劳fatigue of soil 土壤疲乏fault 断层fault amplitude 垂直断距fault basin 断层盆地fault bench 断层阶地fault block 断裂地块fault block mountain 断块山fault breccia 断层角砾岩fault bundle 断层束fault clay 断层粘土fault coal 劣质煤fault excarpment 断层崖fault facet 断层三角面fault fissure 断层裂缝fault fold 断层褶皱fault gouge 耳巴泥fault graben 地堑fault line 断层线fault line scarp 断层线崖fault line valley 断层线谷fault mountain 断层山fault movements 断层运动fault shoreline 断层海岸线fault surface 断面fault topography 断层地形fault trace 断层迹线fault valley 断层谷fault zone 断层带fauna 动物群faunal district 动物区域faunal kingdom 动物界faunal province 动物省faunal region 动物区faunal remains 动物残屑faunistic complex 动物复合体fayalite 铁橄榄石feather fracture 羽毛状断裂feather grass steppe 针茅草原feather joint 羽毛节理feathery structure 羽毛状结构feature extraction 特臻取feature geological map 专门性地质图feature hydrogeological map 专门性水文地质图feature point 特浙feature selection 特铡择feed crop 饲料罪feed unit 饲料单位feedback 反馈feeding area 摄食区域feldspar 长石feldspathization 长石化酌feldspathoids 类长石felling 伐木felse oat meadow 三毛草草甸felsite 长英岩felsitic texture 霏细结构felsophyre 霏细斑岩fen 沼泽fen clay 沼地粘土fen peat 低位泥炭fen soil 低位沼泽土fergusonite 褐钇铌矿ferment 酵素fermentation 发酵fermium 镄fern plot 蕨类种植园fernery 蕨类种植园ferns 蕨类ferralic arenosols 铁铝红砂土ferralic cambisols 铁铝始成土ferrallitic soils 铁铝土ferrallitization 铁铝质土化ferralsols 铁铝土ferric acrisols 铁质强淋溶土ferric luvisols 铁质淋溶土ferric podzols 铁质灰壤ferric siallitic soil 铁质硅铝土ferrimolybdite 铁钼华ferrimontmorillonite 铁蒙脱石ferrimorphic soil 铁成土ferromagnetism 铁磁性ferrudalf 铁质湿淋溶土ferruginization 铁质化ferruginous alteration product 铁质交替产物ferruginous concretions 铁结核ferruginous sandstone 铁质砂岩ferrum 铁ferry 渡船fertile pasture 能齐牧草场fertile soil 肥沃土fertility degree 肥力等级fertilization 施肥fertilizer formula 肥料配合式fertilizer requirement 需肥量festoon islands 花彩列岛fiber 纤维fiber optic image transmission 光纤传象fiber plant 纤维植物fibrist 低分解有机土fibrous peat 纤维质泥炭fibrous root 纤维根fibrous structure 纤维结构fibrovascular bundle 维管束fiducial marks 框标field 场field capacity 田间持水量field check 野外检查field crops 罪field culture 饲料罪field data collection 野外数据收集field evapotranspiration 农田蒸散field experiment 田间试验field fortification 野战筑城field geology 野外地质学field mapping 野外填图field measurement 野外测量field microclimate 农田小气候field moisture capacity 田间持水量field moisture deficiency 田间水分不足field moisture equivalent 田间水分当量field observation 野外观测field of gravity 重力场field of view 视场field sketch 外业草图field station 野外测站field stereoscope 野外立体镜field survey 野外测量field water capacity 田间持水量field weed 杂草field work 野外工作外业fifteen atmosphere percentage 15大气压百分率figure 图形figure of the earth 地球形状filar cross 十字丝file 文件filling 普染filling up of a depression 气旋填塞查字典地理网有全面的地理知识,欢迎大家继续阅读学习。
2021年第5期(总第49卷第363期) No. 5 in 2021 (Total Vol. 49,No. 363 >建筑节能(中英文)Journal of BEE■生态•建筑•环境Ecology • Building • Environmentdoi : 10.3969/j.issn.2096-9422.2021.05.024热舒适指标在寒地冬季校园空间的适用性研究+席天宇、雷永生2’3,王澍2’3,秦欢2’3(1.东北大学江河建筑学院,沈阳110000; 2.哈尔滨工业大学建筑学院,哈尔滨150006;3.寒地城乡人居环境科学与技术工业和信息化部重点实验室,哈尔滨150001)摘要:热舒适指标作为表征室外空间舒适程度的主要依据,其在不同气候区的适用性是影响室外热环境评价结果的关键因素,为了分析不同热舒适指标在中国严寒地区城市室外空间的适用性,以哈尔滨市大学校园室外空间为例,通过气象参数实测和问卷调查的方式,获得了校园典型空间中受访者的主观热感觉投票和微气候参数,并选取3个统计指标和2个定性指标作为室外热舒适指标的适用性量化指标,对比分析了标准有效温度S E T*、生理等效温度P E T、通用热气候指标U T C I对寒地大学校园室外空间热舒适的预测性能。
P E T的预测力和表现力较好,其总体预测和分类预测准确度均较高且Spearm an相关分析表明P E T的預测值与受访者真实热感觉值相关性较强。
在冬季寒地校园热环境评价时应优选P E T作为预测指标,S E T*和U T C I可作为参考评价指标。
关键词:热舒适指标;严寒地区;校园空间;适用性中图分类号:TU2 文献标志码:A文章编号:2096-9422(2021 )05-0126~08Applicability of Thermal Comfort Indices on Campus in Winterin Severely Cold AreaXI Tian-yu, LEI Yong-sheng~'}, WANG Shu2 J , QIN Huan2 J(1. JangHo Architecture,Northeastern University,Shenyang110000, China;2. School o f Architecture,Harbin Institute o f Technology,Harbin150006, C hina;3. Key Laboratory o f Cold Region Urban and Rural Human Settlement Enviroment Science and T echnology,Ministry o f Industry and Information Technolgy,Harbin150001 ,C hina)Abstract :The thermal comfort index is the main basis to express the comfort degree of outdoor space,and its applicability in different climate areas is the key factor to affect the results of outdoor thermal environment evaluation. In order to analyze the applicability of thermal comfort indices on campus in winter in severely cold area, this paper takes the outdoor space of Harbin University as an example,through the measurement of meteorological parameters and questionnaire survey. The subjective heat feeling voting and microclimate parameters of the interviewees in the typical campus space were obtained.Three statistical indexes and two qualitative indexes are selected as the applicable quantitative standards of outdoor thermal comfort index. The prediction performance of physiological equivalent temperature(PET), standard effective temperature {SET*) and universal thermal climate index( UTCI) for outdoor thermal comfort of cold university campus is analyzed. The prediction and performance of PET are better than others, and its overall prediction and classification prediction accuracy are the highest and the Spearman correlation coefficient is also the highest. PET should be the first choice evaluation index of outdoor thermal environment in severely cold areay SET* and UTCI can be used as reference evaluation indexes.Keywords:thermal comfort indices;severely cold region;cam pus;applicability收稿日期:202046-27;修回日期:202105-19*基金项目:国家自然科学基金资助顶目(51438005)126丨席天宇,等:热舒适指标在寒地冬季校园空M的适用性研究〇引言当下经济持续提升的同时,人们也在不断追求高 品质的休闲空间。
ISO 2018年发布的新标准: 纺织服装类ISO 811:2018Textiles -- Determination of resistance to water penetration -- Hydrostatic pressure test纺织品—抗渗水性的测定--静水压试验ISO 1833-6:2018Textiles -- Quantitative chemical analysis-- Part 6: Mixtures of viscose, certain types of cupro, modal or lyocell with certain other fibres (method using formic acid and zinc chloride)纺织品--定量化学分析--第6部分:粘胶纤维、某些铜氨纤维、莫代尔或莱赛尔与某些其他纤维的混合物(甲酸和氯化锌法)ISO 1833-20:2018Textiles -- Quantitative chemical analysis-- Part 20: Mixtures of elastane with certain other fibres (method using dimethylacetamide)纺织品--定量化学分析--第20部分:弹性纤维与某些其他纤维的混合物(二甲基乙酰胺法)ISO 1833-27:2018Textiles -- Quantitative chemical analysis-- Part 27: Mixtures of cellulose fibres with certain other fibres (method using aluminium sulfate)纺织品--定量化学分析--第27部分:纤维素纤维与某些其他纤维的混合物(硫酸铝法)ISO 3175-4:2018Textiles -- Professional care, drycleaning and wetcleaning of fabrics and garments -- Part 4: Procedure for testing performance when cleaning and finishing using simulated wetcleaning纺织品—纺织品和服装的专业维护、干洗和湿洗--第4部分:使用模拟湿洗法清洗和整理时性能试验的程序ISO 8559-3:2018Size designation of clothes -- Part 3:Methodology for the creation of body measurement tables and intervals服装号型--第3部分:创建身体测量表和间隔的方法ISO 10290:2018Textiles -- Cotton yarns -- Basis for specification纺织品--棉纱线—分类基础ISO 15487:2018Textiles -- Method for assessing appearanceof apparel and other textile end products after domestic washing and drying纺织品--服装和其他纺织制品经家庭洗涤和干燥后评估外观的方法ISO 15496:2018Textiles -- Measurement of water vapour permeability of textiles for the purpose of quality control纺织品--质量控制用的纺织品透湿性测试方法ISO/TR 17881-3:2018Textiles -- Determination of certain flameretardants -- Part 3: Chlorinated paraffin flame retardants纺织品--某些阻燃剂的测定第3部分:氯化石蜡阻燃剂ISO 18254-2:2018Textiles -- Method for the detection and determination of alkylphenol ethoxylates (APEO) --Part 2: Method using NPLC纺织品--烷基酚聚氧乙烯醚(APEO)的检测与测定方法第2部分:NPLC 法ISO 18890:2018Clothing -- Standard method of garment measurement服装--服装测量的标准方法ISO 20158:2018Textiles -- Determination of water absorption time and water absorption capacity of textile fabrics纺织品—织物吸水时间和吸水能力的测定ISO 20418-1:2018Textiles -- Qualitative and quantitative proteomic analysis of some animal hair fibres -- Part 1: Peptide detectionusing LC-ESI-MS with protein reduction纺织品--某些动物毛纤维的定性和定量蛋白质组学分析--第1部分:用带蛋白质还原的液相色谱质谱(LC-ESI-MS)进行肽测定ISO 20418-2:2018Textiles -- Qualitative and quantitative proteomic analysis of some animal hair fibres -- Part 2: Peptide detectionusing MALDI-TOF MS纺织品--某些动物毛纤维的定性和定量蛋白质组学分析--第2部分:用激光辅助基质解析电离飞行时间质谱(MALDI-TOF-MS)进行肽测定ISO 20754:2018Textiles -- Man-made fibres -- Determination of shape factors in cross section纺织品--化学纤维--截面异形度的测定ISO 20920:2018Textiles -- Man-made fibres --Determination of dye uptake of cationic dyeable modified polyester fibres纺织品--化学纤维--阳离子染料可染改性涤纶上色率的测定ISO 20932-1:2018Textiles -- Determination of the elasticity of fabrics -- Part 1: Strip tests 纺织品--织物弹性的测定--第1部分:条样试验ISO 20932-2:2018Textiles -- Determination of the elasticity of fabrics -- Part 2: Multiaxial tests纺织品--织物弹性的测定--第2部分:多轴试验ISO 20932-3:2018Textiles -- Determination of the elasticity of fabrics -- Part 3: Narrow fabrics纺织品--织物弹性的测定--第3部分:窄幅织物ISO 21046:2018Silk -- Test method for determining the size of silk yarns丝--蚕丝纱线纤度试验方法ISO 21232:2018Textiles -- Determination of moisturizing effect of textile materials by measurement of microclimate between textiles andsimulated human skin using sweating guarded hotplate纺织品—用热阻湿阻测试仪测量纺织品和模拟的人体皮肤之间的微气候来测定纺织材料的保湿效果ISO 12957-1:2018Geosynthetics -- Determination of friction characteristics -- Part 1: Direct shear test土工合成材料--摩擦特性的测定--第1部分:直接剪切试验ISO 13438:2018Geosynthetics -- Screening test method for determining the resistance of geotextiles and geotextile-related products tooxidation土工合成材料--测定土工织物及其相关产品抗氧化性的筛选试验方法ISO 1419:2018Rubber- or plastics-coated fabrics --Accelerated-ageing tests橡胶或塑料涂覆织物--加速老化试验ISO 32100:2018Rubber- or plastics-coated fabrics --Physical and mechanical tests -- Determination of flex resistance by the flexometer method橡胶或塑料涂覆织物--物理和机械试验—用挠度仪测定耐折性能ISO 10325:2018Fibre ropes -- High modulus polyethylene --8-strand braided ropes,12-strand braided ropes and covered ropes纤维绳-高模量聚乙烯--8股、12股编绳和复编绳索ISO 18692-1:2018Fibre ropes for off shore station keeping --Part 1: General specification 海上定位用纤维绳--第1部分:通用规范ISO 20615:2018Fibre ropes -- Electrostatic surface potential measuring method纤维绳--静电表面电位测量方法。
