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Basic data
| Standard ID | GB/T 40344.3-2024 (GB/T40344.3-2024) |
| Description (Translated English) | Vacuum technology - Standard methods for measuring vacuum pump performance - Part 3: Specific parameters for mechanical booster vacuum pumps |
| Sector / Industry | National Standard (Recommended) |
| Classification of Chinese Standard | J78 |
| Classification of International Standard | 23.160 |
| Word Count Estimation | 22,219 |
| Date of Issue | 2024-04-25 |
| Date of Implementation | 2024-04-25 |
| Issuing agency(ies) | State Administration for Market Regulation, China National Standardization Administration |
GB/T 40344.3-2024: Vacuum technology - Standard methods for measuring vacuum pump performance - Part 3: Specific parameters for mechanical booster vacuum pumps
---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.
ICS 23:160
CCSJ78
National Standards of People's Republic of China
Vacuum technology - Standard method for measuring vacuum pump performance
Part 3: Specific parameters for mechanical booster pumps
(ISO 21360-3:2019, IDT)
Released on 2024-04-25
2024-04-25 implementation
State Administration for Market Regulation
The National Standardization Administration issued
Table of Contents
Preface III
Introduction IV
1 Scope 1
2 Normative references 1
3 Terms and Definitions 1
4 Symbols 2
5 Test conditions 2
6 Test equipment 3
6:1 Basic Requirements 3
6:2 Schematic diagram 3
6:3 Test cap on test pump 4
6:4 Buffer tank on the foreline 5
6:5 Vacuum gauge 5
7 Test methods 5
7:1 Measurement of the maximum allowable pressure difference (Δpmax) 5
7:2 Compression ratio (K0) test report 5
7:3 Measurement of effective compression ratio (Keff) 6
7:4 Measurement of the pressure difference (Δp1) of the relief valve 6
8 Test Report 7
8:1 General Principles 7
8:2 Pump parameter report 7
8:3 Test equipment and condition report 7
8:4 Operation Parameter Report 7
Appendix A (Normative) Test hood 8
Appendix B (Informative) Foreline and Return Cooling Gas Pipeline 9
Appendix C (Informative) Measurement Uncertainty 11
Reference 13
Foreword
This document is in accordance with the provisions of GB/T 1:1-2020 "Guidelines for standardization work Part 1: Structure and drafting rules for standardization documents"
Drafting:
This document is part 3 of GB/T 40344 "Vacuum Technology Standard Method for Measurement of Vacuum Pump Performance": GB/T 40344 has been issued
The following parts are published:
--- Part 1: General requirements;
--- Part 2: Positive displacement vacuum pumps;
--- Part 3: Specific parameters for mechanical booster pumps:
This document is equivalent to ISO 21360-3:2019 "Vacuum technology - Standard methods for measuring vacuum pump performance - Part 3: Mechanical booster pumps"
Specific parameters of
Please note that some of the contents of this document may involve patents: The issuing organization of this document does not assume the responsibility for identifying patents:
This document was proposed by the China Machinery Industry Federation:
This document is under the jurisdiction of the National Vacuum Technology Standardization Technical Committee (SAC/TC18):
This document was drafted by: Zhejiang Vacuum Equipment Group Co:, Ltd:, Zibo Vacuum Equipment Factory Co:, Ltd:, Zhejiang Feiyue Electromechanical Co:, Ltd:,
Shenyang Huizhen Vacuum Technology Co:, Ltd:, Hunan Weige Magnetic Fluid Co:, Ltd:, Bozhong (Shandong) Industrial Equipment Co:, Ltd:, Anhui Wanrui
Lengdian Technology Co:, Ltd:, Guangzhou Tushi Jingyi Technology Co:, Ltd:, Huizhou Yuzhiguang Technology Co:, Ltd:, Guangdong Weiwo Technology Co:, Ltd:,
Shenzhen Huaxing Hengtai Pump & Valve Co:, Ltd:, Shanghai Hanzhong Precision Machinery Co:, Ltd:, Hunan Kellite Pump Industry Co:, Ltd:, Shenzhen Hengyun Changzhen
Air Technology Co:, Ltd:, China National Nuclear Corporation Seventh Research and Design Institute Co:, Ltd:, Hangzhou Xinanjiang Industrial Pump Co:, Ltd:, Sichuan Xintu Fluid Control Technology
Co:, Ltd:, Taixing New Industrial Pump Factory, Nanjing Vacuum Pump Factory Co:, Ltd:, Taizhou University, Zhejiang Boya Precision Machinery Co:, Ltd:, Foshan City
Boton Optoelectronics Technology Co:, Ltd:, Zhongshan Torch Vocational and Technical College, Beijing Tongjia Hongrui Technology Co:, Ltd:, Shenyang Vacuum Technology Research Institute
Limited company:
The main drafters of this document are: Xu Tao, Luo Gensong, Zhong Yunhui, Wang Xilong, Xu Fajian, Jiang Yourong, Song Qingzhu, Qiao Zhonglu, Yan Jichun, Wang Gongfa,
Zengan Jia, Huaikuang Ding, Jinhong Tu, Zhenlan Jiang, Haiying Zhang, Yingshen Xiong, Na Fu, Xia Li, Jun Xiong, Weiping Le, Hao Yan, Yu Fang, Weiping Qiu, Jun Yang,
Dai Guangrong, Zheng Xinyu, Hu Shiling, Feng Lei, Zhang Li, Zhang Yongju, Lu Xuegui, Wu Xiaoyun, Ji Ming, Liu Weiji, Shi Peng, Wei Min, He Zanzan, Wang Lingling:
Introduction
The original vacuum pump standard system puts forward different requirements for the measurement of certain types of vacuum pump performance parameters, measurement devices and performance
The measurement methods and other contents are often repeated and not clearly stated: The formulation of specific vacuum pump standards is based on the overall requirements and is based on their respective characteristics:
In the event of differences between the measurement method for a specific vacuum pump and the general requirements, the specific standard shall be used:
GB/T 40344 "Vacuum Technology Standard Method for Measurement of Vacuum Pump Performance" aims to provide a comprehensive and reliable vacuum pump performance test method based on the commonality and characteristics of vacuum pump performance:
The standard measurement method, namely the general requirements and specific vacuum pump standards, is planned to consist of six parts:
--- Part 1: General requirements: Aims to provide a basic document for measuring vacuum pump performance parameters and simplify future
The vacuum pump standard is formulated: It includes three methods for measuring volume flow rate, as well as the basic pressure, compression ratio and critical pressure of the vacuum pump:
Method for measuring level pressure:
--- Part 2: Volumetric vacuum pumps: Aims to supplement the standard method for performance measurement of volumetric vacuum pumps based on general requirements:
The test method includes the measurement of volume flow rate, base pressure, water vapor tolerance, power consumption and minimum start-up temperature of positive displacement vacuum pumps:
--- Part 3: Specific parameters of mechanical booster pumps: Aims to describe the maximum allowable pressure difference, effective compression ratio, zero flow
Measurement methods and special requirements for compression ratio and relief valve pressure difference:
--- Part 4: Turbomolecular pumps: Aims to provide standard methods for measuring the performance of turbomolecular pumps based on general requirements:
Replenish:
--- Part 5: Non-evaporable getter pumps: Aims to provide a standard method for measuring the performance of non-evaporable getter pumps based on general requirements:
To be supplemented:
--- Part 6: Cryogenic vacuum pumps: Aims to provide a standard method for measuring the performance of cryogenic vacuum pumps based on general requirements:
Replenish:
Vacuum technology - Standard method for measuring vacuum pump performance
Part 3: Specific parameters for mechanical booster pumps
1 Scope
This document describes the measurement methods and procedures for the maximum allowable differential pressure, effective compression ratio, zero flow compression ratio and relief valve differential pressure of mechanical booster pumps:
special requirements:
This document applies to mechanical booster pumps for medium vacuum or rough vacuum applications, including air-cooled mechanical booster pumps and multi-stage mechanical booster pump systems:
This document covers the mechanical booster characteristics of mechanical booster pumps that differ from common positive displacement vacuum pumps: Maximum allowable pressure difference (Δpmax), effective pressure
The compression ratio (Keff), the zero flow compression ratio (K0) and the overflow valve pressure difference (Δp1) are specific parameters of the mechanical booster pump performance:
2 Normative references
The contents of the following documents constitute the essential clauses of this document through normative references in this document:
For referenced documents without a date, only the version corresponding to that date applies to this document; for referenced documents without a date, the latest version (including all amendments) applies to
This document:
ISO 3529-1 Vacuum technology-Vocabulary-Part 1: General terms
General terms)
Note: GB/T 3163-2007 Vacuum technical terms (ISO 3529:1981, MOD)
ISO 3529-2 Vacuum technology terminology Part 2: Vacuum pumps and related terms
Note: GB/T 3163-2007 Vacuum technical terms (ISO 3529:1981, MOD)
Note: GB/T 34873-2017 Vacuum gauge calibration by direct comparison with a standard vacuum gauge (ISO 3567:2011, IDT)
ISO 21360-1:2012 Vacuum technology Standard methods for measuring vacuum pump performance Part 1: General requirements (Vacuumtech-
Note: GB/T 40344:1-2021 Vacuum technology Standard method for measuring vacuum pump performance Part 1: General requirements (ISO 21360-1:2020, IDT)
3 Terms and definitions
For the purpose of this document, the terms and definitions defined in ISO 3529-1 and ISO 3529-2 and the following apply:
3:1
Based on the mechanical principle, it is used between the foreline pump and the high vacuum pump or process chamber to improve the exhaust system in medium vacuum or rough vacuum applications:
A vacuum pump that reduces the volume flow rate required by the foreline pump by either increasing the flow rate or improving the compression within the system:
Note 1: Multiple mechanical booster pumps can be connected in series to obtain higher performance:
NOTE 2 In some applications, a mechanical booster pump is also used for gas recirculation:
[Source: ISO 3529-2:1981, 2:4:6, modified - added the expressions "based on mechanical principles" and "or process chamber", replaced by "medium vacuum"
The term “mid-pressure range” is replaced by “application or rough vacuum application” and the term “pressure distribution” is replaced by “compression”:]
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