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GB/T 33061.5-2023: Plastics - Determination of dynamic mechanical properties - Part 5: Non-resonance method under flexural vibration
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Plastics - Determination of dynamic mechanical properties - Part 5: Non-resonance method under flexural vibration
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GB/T 33061.5-2023
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Basic data | Standard ID | GB/T 33061.5-2023 (GB/T33061.5-2023) | | Description (Translated English) | Plastics - Determination of dynamic mechanical properties - Part 5: Non-resonance method under flexural vibration | | Sector / Industry | National Standard (Recommended) | | Classification of Chinese Standard | G31 | | Classification of International Standard | 83.080.01 | | Word Count Estimation | 18,169 | | Date of Issue | 2023-08-06 | | Date of Implementation | 2024-03-01 | | Issuing agency(ies) | State Administration for Market Regulation, China National Standardization Administration | GB/T 33061.5-2023: Plastics - Determination of dynamic mechanical properties - Part 5: Non-resonance method under flexural vibration
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ICS 83.080.01
CCSG31
National Standards of People's Republic of China
Determination of dynamic mechanical properties of plastics
Part 5.Non-resonant bending vibration method
Part 5.Flexuralvibration-Non-resonancemethod,MOD)
Published on 2023-08-06
2024-03-01 Implementation
State Administration for Market Regulation
Released by the National Standardization Administration Committee
Foreword
This document complies with the provisions of GB/T 1.1-2020 "Standardization Work Guidelines Part 1.Structure and Drafting Rules of Standardization Documents"
Drafting.
This document is Part 5 of GB/T 33061 "Determination of Dynamic Mechanical Properties of Plastics". GB/T 33061 has issued the following
part.
---Part 1.General principles;
---Part 4.Non-resonant tensile vibration method;
---Part 5.Non-resonant bending vibration method;
---Part 6.Non-resonant shear vibration method;
---Part 7.Non-resonant torsional vibration method;
---Part 10.Determination of complex shear viscosity using a parallel plate oscillating rheometer;
---Part 11.Glass transition temperature.
This document is modified to adopt ISO 6721-5.2019 "Determination of dynamic mechanical properties of plastics Part 5.Non-resonant bending vibration"
Law".
Compared with ISO 6721-5.2019, this document has many structural adjustments. Comparison list of structure number changes between two files
See Appendix A for the table.
Compared with ISO 6721-5.2019, there are many technical differences between this document and the clauses involved in the outer margin of the page.
Single lines (|) are marked. A list of these technical differences and their causes is shown in Appendix B.
The following editorial changes have been made to this document.
---In order to coordinate with the existing standards, the name of the standard is changed to "Determination of dynamic mechanical properties of plastics - Part 5.Non-resonant bending vibration"
"Movement Method";
---Replaced ISO 6721-6 with the informative reference GB/T 33061.6, and GB/T 33061.1 replaced ISO 6721-1 (see
Chapter 1);
---Explanation of the symbol k%00."The cross-sectional size of the steel specimen is the maximum size that the clamp can accommodate. The stiffness of the specimen is greater than that of the plastic specimen to be tested.
The material height is at least 100 times (see Note 2)" is changed to Note 1 (see 3.2);
--- Added a note "about using a torque wrench to maintain a fixed clamping force on the specimen and improve the reproducibility of the test" (see 9.3);
---Added Appendix A (informative) "List of comparison of structure numbers between this document and ISO 6721-5.2019";
---Added Appendix B (informative) "List of technical differences between this document and ISO 6721-5.2019 and their reasons".
Please note that some content in this document may be subject to patents. The publisher of this document assumes no responsibility for identifying patents.
This document is proposed by China Petroleum and Chemical Industry Federation.
This document is under the jurisdiction of the National Plastics Standardization Technical Committee (SAC/TC15).
This document was drafted by. Zhonglan Chenguang Chemical Research and Design Institute Co., Ltd., Chengde Precision Testing Machine Co., Ltd., Waters Technology (Part 1)
Hai) Co., Ltd., NETZSCH Scientific Instrument Trading (Shanghai) Co., Ltd., Xiamen David Technology Co., Ltd., Zhejiang Xiangguang Biotechnology Co., Ltd.
The company, Sinopec (Beijing) Chemical Research Institute Co., Ltd., Fuan Yadong Electric Co., Ltd., Liaocheng University, Jilin Provincial Product Quality Supervision and Inspection
Inspection Institute, Dongguan Xiangzhijing E-Commerce Co., Ltd., Qingdao Hairong Commercial Cold Chain Co., Ltd., Qingdao Dianshi Stationery Co., Ltd.,
Mettler Toledo Technology (China) Co., Ltd., Qingdao Dagang Customs of the People's Republic of China.
The main drafters of this document. Cao Jinpeng, Wang Xinhua, Guo Yanshuang, Wang Rong, Feng Ruzhi, Fang Yong, Liu Xuanbo, Chen Wenwei, Teng Mouyong, Sun Xiaozhong,
Li Shangyu, Lin Yalun, Hu Xiuzhen, Wang Yuanhong, Yuan Ningxiao, Gao Jianguo.
Introduction
Dynamic mechanical analysis (DMA) measures the response of a material under alternating stress or strain under programmed temperature control. The measurement results reflect the material's response to alternating stress or strain.
The viscoelasticity of the material.
This document uses the DMA method to determine the storage modulus, loss modulus and loss factor as a function of temperature in non-resonant bending modes of plastics.
change. According to the above results, the glass transition, secondary relaxation, crystallization, cross-linking, phase separation, etc. of the plastic can be characterized. The above physical quantities determine the plastic
Important parameters for using features.
GB/T 33061 specifies various methods for determining the dynamic mechanical properties of rigid plastics within the range of linear viscoelastic behavior. It is planned to consist of twelve
Partial composition.
---Part 1.General principles. The purpose is to establish common definitions and various aspects of test methods for the determination of dynamic mechanical properties.
---Part 2.Twist method. The purpose is to establish an operable, traceable and verifiable method for the measurement of energy storage and loss components of torsional modulus.
Real program.
---Part 3.Resonant bending vibration curve method. The purpose is to obtain the bending composite modulus Ef* of the homogeneous plastic and the layer used for sound insulation.
Determine the damping characteristics of compressed plastics and establish operable, traceable and verifiable procedures.
---Part 4.Non-resonant tensile vibration method. The purpose is to determine the forced non-resonance method of the tensile complex modulus E* of plastics.
Establish operable, traceable, and verifiable procedures.
---Part 5.Non-resonant bending vibration method. The purpose is to determine the forced non-resonance method of the plastic bending complex modulus Ef*.
Establish operable, traceable, and verifiable procedures.
---Part 6.Non-resonant shear vibration method. The purpose is to determine the forced non-resonant method of plastic shear complex modulus G*,
Establish operable, traceable and verifiable procedures.
---Part 7.Non-resonant torsional vibration method. The purpose is to calculate the torsion of the shear complex modulus G* of a strip or rod-shaped solid polymer.
Convert the measurement to non-resonant methods and establish operable, traceable and verifiable procedures.
---Part 8.Wave conduction longitudinal shear vibration method. The purpose is to calculate the longitudinal complex modulus L* and shear complex modulus of the polymer
For the determination of the energy storage component of G*, establish an operable, traceable and verifiable procedure.
---Part 9.Sonic pulse propagation tensile vibration method. The purpose is to measure the storage component of polymer composite tensile modulus E*.
Determine and establish operable, traceable and verifiable procedures.
---Part 10.Determination of complex shear viscosity using a parallel plate oscillating rheometer. The purpose is to provide dynamic rheological properties of polymer melts.
Determination of test methods and establishment of operable, traceable and verifiable procedures.
---Part 11.Glass transition temperature. The purpose is to determine the glass transition temperature (Tg) for dynamic mechanical properties.
Establish operable, traceable and verifiable procedures.
---Part 12.Non-resonant compression vibration method. The purpose is to establish an operable and practical method for the determination of the compression composite modulus E* of polymers.
Traceable and verifiable procedures.
Determination of dynamic mechanical properties of plastics
Part 5.Non-resonant bending vibration method
1 Scope
This document describes the forced non-resonance method for the determination of the complex bending modulus Ef* of plastics in the frequency range 0.01Hz~100Hz.
Note. Higher frequencies may lead to larger errors in the measured dynamic performance (see 9.5.1 and 10.1.2).
This document is suitable for the determination of dynamic storage modulus between 10MPa and.200GPa. This document can study materials with a modulus less than 10MPa.
However, the shear vibration method can be used to more accurately measure its dynamic mechanical properties (see GB/T 33061.6).
This document is particularly suitable for the determination of loss factors greater than 0.02, in order to facilitate the study of the dynamics of most glassy-rubbery relaxation zones.
Can change with temperature and frequency (see GB/T 33061.1).
2 Normative reference documents
The contents of the following documents constitute essential provisions of this document through normative references in the text. Among them, the dated quotations
Only the version corresponding to the date applies to this document; for undated referenced documents, the latest version (including all amendments) applies to this document.
document.
GB/T 33061.1 Determination of dynamic mechanical properties of plastics Part 1.General principles (GB/T 33061.1-2016, ISO 6721-1.
2011,MOD)
3 Terms, definitions and symbols
3.1 Terms and definitions
The terms and definitions defined in GB/T 33061.1 apply to this document.
3.2 Symbols
The following symbols apply to this document.
b. Specimen width, unit is meter (m).
E'fa, E'f. apparent value and correction value of bending storage modulus, unit is Pascal (Pa).
E″f. bending loss modulus, unit is Pascal (Pa).
f. Measurement frequency, unit is Hertz (Hz).
fF. Resonant frequency of the force sensor, unit is Hertz (Hz).
fs. Resonant frequency of the sample, unit is Hertz (Hz).
G'. Shear storage modulus, unit is Pascal (Pa).
h. Thickness of sample, unit is meter (m).
ka,k. the measured value and correction value of the specimen's complex stiffness, in Newtons per meter (N/m).
kF. Stiffness value of the force sensor, unit is Newton per meter (N/m).
k%00.Stiffness value of steel sample, unit is Newton per meter (N/m).
La. (for clamped specimens) the length of the specimen between the central clamp and each outer end clamp, in meters (m); (for simply supported beam specimens
The length of the specimen between the center load line of the specimen and each outer end support, in meters (m).
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