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GB/T 36370-2018 English PDF

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GB/T 36370-2018: Cleanroom and associated controlled environments -- Guidelines of application of air filters
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GB/T 36370-2018919 Add to Cart 7 days Cleanroom and associated controlled environments -- Guidelines of application of air filters Valid

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Basic data

Standard ID: GB/T 36370-2018 (GB/T36370-2018)
Description (Translated English): Cleanroom and associated controlled environments -- Guidelines of application of air filters
Sector / Industry: National Standard (Recommended)
Classification of Chinese Standard: C70
Classification of International Standard: 13.040.35
Word Count Estimation: 46,499
Date of Issue: 2018-06-07
Date of Implementation: 2018-10-01
Issuing agency(ies): State Administration for Market Regulation, China National Standardization Administration

GB/T 36370-2018: Cleanroom and associated controlled environments -- Guidelines of application of air filters


---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.
Cleanroom and associated controlled environments--Guidelines of application of air filters ICS 13.040.35 C70 National Standards of People's Republic of China Clean room and related controlled environment Air Filter Application Guide Published on.2018-06-07 2018-10-01 implementation State market supervision and administration China National Standardization Administration issued

Content

Foreword I 1 Scope 1 2 Normative references 1 3 Terms and Definitions 1 4 efficiency rating 3 5 ordinary filter 3 6 chemical filter 5 7 Common Air Filter Standard 6 Appendix A (informative) Air filter efficiency classification and identification 7 Appendix B (informative) High efficiency filter factory test method 14 Appendix C (informative) Filter on-site leak detection instructions 18 Appendix D (informative) Other notes 19 Appendix E (informative) High efficiency filter example 22 Appendix F (informative) Performance test for chemical air filters 25 Appendix G (informative) Air Filter Standard Catalog 39

Foreword

This standard was drafted in accordance with the rules given in GB/T 1.1-2009. This standard is proposed and managed by the National Cleanroom and Related Controlled Environment Standardization Technical Committee (SAC/TC319). This standard was drafted. Suzhou Huatai Air Filter Co., Ltd., Nanjing Tianjia Environmental Technology Co., Ltd., Suzhou Metrology Test Research Research Institute, Yantai Baoyuan Purification Co., Ltd., Aimeike Air Filter (Suzhou) Co., Ltd., Changzhou Xiangming Intelligent Power Co., Ltd., Zhongzhong National Electronic Engineering Design Institute, Suzhou Purification Engineering Installation Co., Ltd., Suzhou Industrial Park Jiahe Environmental Technology Engineering Co., Ltd., Texas Aihe Filtration Equipment Co., Ltd., Zhejiang Jinhai Environmental Technology Co., Ltd., Tianjin Longchuan Purification Engineering Co., Ltd., Meyer (China) Environment Purification Co., Ltd., Heshi (Suzhou) Special Materials Co., Ltd., Suzhou Yingdel Indoor Air Technology Co., Ltd., Suzhou Enweite Environment Technology Co., Ltd., China Power Investment Engineering Research and Testing Center, China Standardization Association, Beijing Xida Construction Supervision Co., Ltd., Beijing Shiyuan Hida Engineering Technology Co., Ltd., China Electronics Society Clean Technology Branch, Suzhou Kejia Environmental Technology Co., Ltd. Company, Zhongtian Daocheng (Suzhou) Clean Technology Co., Ltd., Shenzhen Xinke Special Decoration Engineering Company. The main drafters of this standard. Cai Jie, Yu Yu, Wang Wei, Tu Guangbei, Ren Zhiwei, Zhang Liqun, Wang Xiaobing, Yu Ziqiang, Yang Ziqiang, He Zhijun, Xu Xiaohao, Jiang Naijun, Yan Wenzhao, An Zhixing, Wu Xiaoquan, Zhang Min, Qian Jing, Ye Weiqiang, Shi Xiaolei, Zhang Shizhong, Zhang Yong, Zhang Lihai, Qi Chuanming, Jiang Yan, Wu Yifeng, Chen Zhongquan, Liu Hui, Li Qidong, Su Gangmin, Yin Xiaodong. Clean room and related controlled environment Air Filter Application Guide

1 Scope

This standard gives the classification of air filter efficiency in clean rooms and related controlled environments and the application elements of various filters. This standard applies to air filters used in clean rooms and related controlled environments.

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. GB/T 25915.3-2010 Clean rooms and related controlled environments - Part 3. Methods GB/T 25915.6-2010 Clean rooms and related controlled environments - Part 6. Vocabulary (ISO 14644-6.2007, IDT) ISO 29463-1.2011 High efficiency air filters and filters - Part 1. grading, performance testing, identification (High-efficiency filtersandfiltermediaforremovingparticlesinair-Part 1.Classification,performancetestingand Marking) ISO 29463-2.2011 High efficiency air filters and filters - Part 2. Aerosol generation, measuring devices, particle count statistics Method (High-efficiencyfiltersandfiltermediaforremovingparticlesinair-Part 2. Aerosolproduc- Tion,measuringequipmentandparticle-countingstatistics)

3 Terms and definitions

The following terms and definitions as defined in GB/T 25915.6-2010 apply to this document. 3.1 Air filter airfilter A filter used to remove suspended particulate matter and certain gaseous pollutants from a gas stream. 3.2 Efficiency efficiency Under test conditions, the ratio of the count rate of the filter or filter material trapping particles to the upstream particle count rate, or the mass concentration and the upper The ratio of the mass concentration of the swim is expressed in %. 3.3 Penetration rate Under the test conditions, the ratio of the particle concentration downstream of the filter to the upstream concentration is expressed in %. 3.4 Most easily penetrated particle size most-penetratingparticlesize; MPPS Particle size for the highest filter penetration (lowest filtration efficiency) for a given filter. Note. It is the most difficult to filter the particle size of the particles. In theory, the filtration efficiency of particles larger or smaller than MPPS is higher than that at MPPS; in practical applications, The MPPS of the filter is a range of particle sizes measured by the instrument, not a unique particle size. 3.5 MPPS efficiency minimumfilterefficiency Under the test conditions, the lowest point of the filter efficiency curve, that is, the efficiency value corresponding to the MPPS. 3.6 Sub-high efficiency filter sub-HEPAfilter Y-HEPA filter Y-HEPAfilter EPA filter EPAfilter A filter with an MPPS efficiency of less than 99.95% but not less than 85% under test air volume. 3.7 High efficiency filter high-efficiency-particulate-air HEPA filter HEPAfilter ISO 35H to ISO 45H, the filter with MPPS efficiency below 99.999% but not less than 99.95% under test air volume. 3.8 Ultra-efficient filter ultrA.low-penetration-air ULPA filter ULPAfilter ISO 50U and higher grade filters, filters with MPPS efficiency of 99.999% under test air volume. 3.9 Sodium flame method A method of detecting filtration efficiency. Sodium chloride aerosol with a specific mass median diameter and specific particle size distribution upstream of the filter The characteristic intensity of the sodium-containing aerosol flame upstream and downstream of the filter was measured by a flame photometer to determine the filtration efficiency. Note. Also known as the "flame photometer method". 3.10 Turbidity meter photometermethod A liquid or solid aerosol with a specific mass median diameter and a specific particle size distribution upstream of the filter, using a light scattering principle photometric test A method of measuring the upstream and downstream aerosol mass concentrations to determine the filtration efficiency. Note. Also known as the "photometer method". Commonly used turbidity meter methods are. traditional DOP method, oil mist method and the like. 3.11 Purification unit fanfilterunit;FFU A filter unit that integrates a HEPA or ULPA filter, a static pressure tank, a fan, and an air speed adjustment device. Note. Also known as "fan filter unit". 3.12 Prefilter prefilter A filter set to protect the next stage filter and extend its life. Note. Also known as "pre-filter". 3.13 Breathing organicoutgas The filter manufactures gaseous compounds that may be released from the material. 3.14 End filter terminalfilter The last stage air filter of the air supply system. 3.15 Adsorption capacity The amount (mass or moles) of a specified adsorbate that can be contained by the filter media in a gas phase air purification plant. Note. Desorption capacity is referred to during desorption. 3.16 Removal efficiency removalefficiency The air chemical filter removes the percentage (%) of the gas phase contaminant or its concentration fraction during the specified test time. 3.17 Pressure drop differentialpressure The pressure difference between the front and rear ends of the air chemical filter. 3.18 Resilience The parameter that measures the desorption capacity of the adsorbent or chemical filter is expressed as the remaining capacity (residual fraction). 3.19 PTFE tensile film filter ePTFEmedia A filter material formed by compounding a polytetrafluoroethylene film and other auxiliary materials. Among them, the filtering material is Teflon drawing A fibrous porous film formed. Note. The PTFE film for making high-efficiency filters is about 10μm~20μm thick, and the fiber diameter is only tens of nanometers. Therefore, it is sometimes called “membrane filtration” material or "Nanofiltration" material. 3.20 Electret filter media electretemedia A polymeric filter material that can store charge for a long period of time.

4 efficiency rating

See Appendix A for air filter efficiency ratings. For the filtration performance of high efficiency air filters, this standard uses ISO 29463-1. For the level specified in.2011, see A.1.

5 ordinary filter

5.1 Overview 5.1.1 Ordinary filters are classified into coarse, medium, high, medium, efficient, efficient and ultra efficient. Coarse, medium and high in the purification air conditioning system Medium-effect as a pre-filter protects the functionality of the various components and protects high-efficiency filters and ultra-efficient filters. 5.1.2 The function and function of the efficient and ultra-efficient filter is to ensure the cleanliness level required by the production process for the environment. The end of the system. 5.2 End High Efficiency Filter 5.2.1 Filtration efficiency Generally, for ISO 6 and lower non-unidirectional flow clean rooms, the end filter has a filtration efficiency no lower than ISO 35H (for the most The filtration efficiency of the easily penetrating particles is not less than 99.95%). If the user agrees with the supplier, the sodium flame method and aerosol turbidity can also be used. The minimum efficiency of the method or other methods is not less than 99.97% or other agreed values. The filtration efficiency of the end filter of ISO Class 5 clean room is not lower than ISO 40H (the filtration efficiency of the most easily penetrated particle size is not Less than 99.99%). If the user agrees with the supplier, a filter with a particle efficiency of not less than 99.99% for 0.3 μm particles can also be used. ISO 4 and higher cleanrooms, the end filter is generally ULPA filter, the filtration efficiency is not lower than ISO 50U Grade (the filtration efficiency at MPPS is not less than 99.999%). 5.2.2 Factory inspection High-efficiency filters with an efficiency specification not lower than ISO 35H shall be tested one by one before leaving the factory. The factory inspection method for efficiency or penetration rate is determined by the customer and the supplier. Appendix B gives possible test methods. If there is no special Do not agree, the particle counting method specified in ISO 29463-2.2011 should be used. Note. The customer and the supplier should agree on the specific test method, whether to use the scanning method or the total efficiency method, and agree on the particle measuring device and test used in the test. Aerosols, test procedures and acceptance limits. 5.2.3 Detection after installation 5.2.3.1 During the test, it is necessary to verify that there is no bypass leakage in the facility, the filter is free of defects (small holes and damage of the filter material and sealing points), no leakage (over Seepage leakage of filter frame and gasket, leakage of filter mount), see Appendix C. This test generally does not determine the filtration of the system. effectiveness. Typically, a sufficient concentration of aerosol occurs upstream of the filter (see Appendix D). Scanning downstream of the filter and around the filter, or Sampling in the air duct downstream of the filter. Note. This test is designed to confirm that the high efficiency filtration system is installed correctly. 5.2.3.2 After installation, the filter is usually tested by the following two methods in B.6.2 and B.6.3 of GB/T 25915.3-2010. a) in-situ filtration system aerosol turbidity meter scanning leak detection; b) In-place filtration system particle counter scan for leak detection. The user can use one of these two methods and refer to the corresponding procedures and acceptance limits. 5.2.3.3 For leak detection of high efficiency filters in air ducts and air handling systems, refer to the square in B.6.4 of GB/T 25915.3-2010. Methods, procedures, and acceptance limits are measured using a particle counter or aerosol turbidimeter. Note. Efficiency testing in the filter manufacturer is performed under ideal test conditions. Differences between site conditions and test conditions and manufacturer conditions may result The results of the on-site inspection and laboratory inspection are inconsistent. Before the on-site inspection after installation, it is recommended that customers, suppliers and testers have on-site inspection methods. And the acceptance limit is agreed. 5.2.4 End filter away from the clean room In some cases, due to factors such as the site, the clean room end filter is located in the air conditioning system, not the air supply port of the clean room. This Design can save investment, but there are some drawbacks. Cleanrooms generally do not use this design unless necessary. 5.2.5 End-of-life filter life The length of life of the end-height filter depends primarily on the design of the filter section of the ventilation system. High efficiency of pre-filter in the system Low determines the life of the end filter. 5.2.6 Other 5.2.6.1 Organic matter and moisture on the end filter are prone to microbial growth. In order to reduce the proliferation of microorganisms, the material of the end efficient filter is not Hydrophilic materials should be used, and materials that are prone to microbial growth should not be used. The separator material with the separator filter should not be hydrophilic, flammable, or Nutritious paper organic material. 5.2.6.2 The filter material in the high efficiency filter is generally a glass fiber filter. The filter media should not contain glass with high sodium and potassium content that is easy to fall back. fiber. 5.2.6.3 Where outgassing may affect the clean environment, the filter shall be constructed of a material with low outgassing. 5.2.6.4 Filters made of electret materials may be inefficient due to the disappearance of static electricity during use. Clean room end filter is not recommended Use electret filter material. 5.2.6.5 Field repair of filters (see Appendix D). 5.2.6.6 Order elements (see Appendix D). 5.2.6.7 Teflon drawn film (ePTFE) filter (see Appendix D). 5.3 pre-filter 5.3.1 Function and selection 5.3.1.1 To protect the next stage filter or end filter, a pre-filter should be provided in the air supply system. Pre-filter efficiency is high and low The cleanliness of the clean room has limited impact, but the filtration efficiency of the pre-filter determines the service life of the protected filter. Pre-filter should have enough Large effective filtration area to ensure a long enough life. 5.3.1.2 Pre-filter before the end filter, the filtration efficiency is generally not less than 90%. 5.3.1.3 In the design, the pre-filter of the end filter is a HEPA filter with ISO 35H efficiency specification, and its air duct and sealing structure Should be reliable. After the filter is installed, it can be scanned for leaks downstream of the HEPA pre-filter. 5.3.2 Replacement 5.3.2.1 The pre-filter section shall have a simple and practical resistance monitoring device, and the information of replacing the pre-filter may be given accurately and intuitively. According to the supplier Or the air conditioner designer's suggestion to replace the pre-filter. 5.3.2.2 In some occasions, when the user requests to replace the pre-filter, the air-conditioning system supplies air as usual. At this time, the replacement of the pre-filter is in the air-conditioning system. When operating and operating, it should be considered for easy maintenance and replacement. 5.4 Example of high efficiency filter selection See Appendix E.

6 chemical filter

6.1 Key parameters of performance The key parameters of air chemical filter performance are as follows. a) pressure drop, ΔP; b) adsorption capacity, ms; c) removal efficiency, E; d) Maintain ability, mr. 6.2 Main factors affecting purification efficiency and service life The main factors affecting filter purification efficiency and service life are as follows. a) The advantages and disadvantages of chemical filter design and processing, the effectiveness of filter media (such as activated carbon, modified activated carbon, etc.), packing density Degree and so on. b) After determining the type and concentration of the polluted gas, a reasonable selection of the formula and ratio of the filling medium will achieve a better purification effect. c) The randomness and uncertainty of the pollution source will seriously affect the adsorption efficiency. d) The amount of air passing directly through the filter, the air volume is increased, the efficiency is reduced, and the life is shortened. e) Relative humidity affects the efficiency of the filter to a certain extent, generally the relative humidity below 70% is not obvious, but when relative When the humidity exceeds 70%~80%, the adsorption efficiency decreases rapidly. f) The gas concentration increases and the service life decreases rapidly. g) In the case of other adsorption parameters unchanged, the efficiency of the re-polluting gas does not reach the height of a single gas, and the chemical properties vary greatly. Especially serious. 6.3 Monitoring and replacement The outlet of the site shall be monitored. If the concentration of pollutants in the airflow exceeds the predetermined value, it shall be replaced immediately. Note 1. The air chemical filter produced by the filter manufacturer has a service life indicator, but this indicator is the knot measured under the test conditions specified by the standard. If it has a service life of one year, it can only be used as a reference. Note 2. Waste filters and activated activated carbon are safe and harmless, but should be avoided during storage and pay attention to fire safety. 6.4 Setting the protection filter It should be considered that the chemical filter itself is dust-producing, and a conventional filter having an efficiency of not less than F7 should be provided above and below it. 6.5 Chemical filter test See Appendix F for chemical filter testing.

7 Common Air Filter Standards

See Appendix G for a list of commonly used air filter standards.

Appendix A

(informative appendix) Air filter efficiency classification and identification A.1 International Standard Filter Grouping and Classification ISO 29463-1.2011 specifies that sub-efficient, efficient and ultra-efficient filters are measured by counting method and filter according to MPPS efficiency. For classification, see Table A.1. The first Arabic digit in the ISO symbol represents n nines, and the second digit represents 5 or 0. E.g, The ISO 45H represents the counting method MPPS effici......
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