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GB/T 42542-2023 (GBT42542-2023)

GB/T 42542-2023_English: PDF (GBT 42542-2023, GBT42542-2023)
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GB/T 42542-2023English245 Add to Cart 0--9 seconds. Auto-delivery Fibre-reinforced composites -- Method for accelerated moisture absorption and supersaturated conditioning by moisture using sealed pressure vessel Valid GB/T 42542-2023

BASIC DATA
Standard ID GB/T 42542-2023 (GB/T42542-2023)
Description (Translated English) Fibre-reinforced composites -- Method for accelerated moisture absorption and supersaturated conditioning by moisture using sealed pressure vessel
Sector / Industry National Standard (Recommended)
Classification of Chinese Standard Q23
Classification of International Standard 83.120
Word Count Estimation 16,146
Date of Issue 2023-05-23
Date of Implementation 2023-12-01
Drafting Organization Beijing FRP Research and Design Institute Co., Ltd., Technical Institute of Physics and Chemistry, Chinese Academy of Sciences, Xinchuang Carbon Valley Holdings Co., Ltd., Beijing FRP Institute Testing Center Co., Ltd., Jushi Group Co., Ltd., China Aviation Development Beijing Aeronautical Materials Research Institute
Administrative Organization National Standardization Technical Committee on Fiber Reinforced Plastics (SAC/TC 39)
Proposing organization China Building Materials Federation
Issuing agency(ies) State Administration for Market Regulation, National Standardization Management Committee

Standards related to: GB/T 42542-2023

GB/T 42542-2023
GB
NATIONAL STANDARD OF THE
PEOPLE’S REPUBLIC OF CHINA
ICS 83.120
CCS Q 23
GB/T 42542-2023 / ISO 22836:2020
Fiber-reinforced Composites - Method for Accelerated
Moisture Absorption and Supersaturated Conditioning by
Moisture Using Sealed Pressure Vessel
纤维增强复合材料 密封压力容器
(ISO 22836:2020, IDT)
ISSUED ON: MAY 23, 2023
IMPLEMENTED ON: DECEMBER 1, 2023
Issued by: State Administration for Market Regulation;
Standardization Administration of the People’s Republic of China.
Table of Contents
Foreword ... 3
1 Scope ... 4
2 Normative References ... 4
3 Terms and Definitions ... 4
4 Principle ... 5
5 Instruments and Equipment ... 6
6 Test Procedures ... 8
7 Precision ... 10
8 Test Report ... 10
Appendix A (informative) Example of CFRP and CFRTP Specimens under
Supersaturated Conditioning by Moisture ... 12
Bibliography ... 16
Fiber-reinforced Composites - Method for Accelerated
Moisture Absorption and Supersaturated Conditioning by
Moisture Using Sealed Pressure Vessel
1 Scope
This document specifies the method for accelerated moisture absorption and supersaturated
conditioning by moisture of fiber-reinforced composites using sealed pressure vessels at a
heating temperature above 100 C and saturated water vapor pressure conditions.
The purpose of this moisture absorption method is to screen materials by mechanical or thermal
properties.
This document is applicable to fiber-reinforced composites with a glass transition temperature
(Tg) greater than 150 C, including carbon fiber-reinforced thermoset composites (CFRP),
carbon fiber-reinforced thermoplastic composites (CFRTP) and glass fiber-reinforced
composites, etc.
2 Normative References
The contents of the following documents constitute indispensable clauses of this document
through the normative references in the text. In terms of references with a specified date, only
versions with a specified date are applicable to this document. In terms of references without a
specified date, the latest version (including all the modifications) is applicable to this document.
ISO 472 Plastics - Vocabulary
NOTE: GB/T 2035-2008 Terms and Definitions for Plastics (ISO 472:1999, IDT)
3 Terms and Definitions
What is defined in ISO 472, and the following terms and definitions are applicable to this
document.
Addresses of the terminology databased maintain by ISO and IEC for standardization are as
follows:
---ISO online browsing platform: http://www.iso.org/obp;
---IEC electronic open platform: http://www.electropedia.org/.
3.1 additional moisture content
Additional moisture content refers to the additional moisture absorption mass of the test
material as a percentage of the initial test material mass.
NOTE: see Formula (1).
3.2 initial moisture content
Initial moisture content refers to the moisture absorption mass percentage of the test material at
the beginning of the moisture absorption test.
NOTE: see Formula (3).
3.3 supersaturated conditioning by moisture
Supersaturated conditioning by moisture refers to the conditioning process, in which, the test
material is cooled from a moisture absorption saturated state of relatively high temperature and
humidity (for example, a relatively high temperature and saturated water vapor pressure) to
room temperature.
3.4 accelerated moisture absorption
In order to obtain the saturated moisture content (3.5) in a shorter time, moisture absorption is
performed under specific conditions of a relatively high temperature (for example, 120 C) and
moisture absorption pressure (for example, 0.2 MPa).
3.5 saturated moisture content
Saturated moisture content refers to the moisture absorption rate obtained when the test material
is cooled from a relatively high temperature (for example, 120 C) to a relatively low
temperature (room temperature) under supersaturated conditioning by moisture.
4 Principle
In order to facilitate the test material to obtain a moisture absorption saturated state that is
almost similar to that at room temperature in a short period of time, the test material is placed
under the conditions of a relatively high temperature and humidity [for example, temperature
120 C and saturated water vapor pressure with air (oxygen) 0.2 MPa] for moisture absorption.
The higher the temperature, the faster the diffusion rate of water molecules inside the material;
the higher the water vapor pressure, the higher the frequency of the material surface absorbing
water molecules from the outside. Therefore, the moisture absorption saturated (or balanced)
state of the material can be obtained in a relatively short period of time. However, if this
moisture absorption saturated material is cooled to room temperature, due to the slow diffusion
rate of water molecules inside the material and the slow-release rate on the material surface, the
material will be in a supersaturated state by moisture absorption.
Through this mode, the supersaturated state by moisture absorption of thermoset and
During heating from room temperature to 120 C, the exhaust system can discharge the air
inside the autoclave when the temperature reaches 100 C.
NOTE: autoclave is known as “high-pressure sterilizer” in the biological and medical industries.
This high-pressure sterilizer differs from the stainless-steel sealed pressure vessel (5.2) in
the chemical industry.
5.6 Vacuum Oven
The vacuum oven can be heated to 200 C under reduced pressure, with a temperature control
accuracy of  1 C.
5.7 Balance
The balance can weigh the specimens, and the resolution shall not be lower than 0.1 mg.
6 Test Procedures
6.1 Specimen Weighing
Use a balance (5.7) to weigh the individual specimens. Before weighing, the specimens should
be conditioned for 24 h at 23 C and 50% RH. Before moisture absorption, the specimens shall
not be dried, so as to avoid any degradation.
6.2 Acquisition of Supersaturated State by Moisture Absorption
Use a support frame to place the specimens in the sealed pressure vessel. The surfaces of the
specimens, the specimens and the sealed pressure vessel will not come into contact with each
other. During moisture absorption, they can be completely immersed in water vapor.
Pour deionized water into the sealed pressure vessel (for example, pour 10 mL ~ 20 mL of
deionized water into a 300 mL sealed pressure vessel).
Seal the sealed pressure vessel and place it in the oven as shown in Figure 1. Open Valve A and
Valve B.
Set the oven temperature to above 100 C, for example, 120 C. When the temperature rises to
about 100 C, at Valve B, release water vapor for a period of time (for example, 1 min ~ 2 min)
to discharge the internal air. Then, close Valve B. At the set temperature, through the pressure
gauge, confirm the water vapor pressure inside the sealed pressure vessel.
NOTE: set the appropriate oven temperature in combination with Tg of the test material and the
temperature of the preparation process.
Continue heating for a determined period of time, for example, 72 h.
6.3 Sampling of Test Material under Supersaturated State by Moisture Absorption
If there is only one sealed pressure vessel in the oven, then stop heating, and cool the sealed
pressure vessel to room temperature. Take the specimens out of the sealed pressure vessel.
If one of the multiple sealed pressure vessels is taken out from the oven, then, close Valve A
and disconnect the connector. After taking the sealed pressure vessel out of the oven, cool it to
room temperature. Open Valve A. Take the specimens out of the sealed pressure vessel.
This test method should use an autoclave (5.5) instead of a sealed pressure vessel and oven.
When using the autoclave, the operating manual shall be followed.
6.4 Confirmation of Saturation by Moisture Absorption
Weigh the specimens of moisture absorption. Then, repeat the test steps 6.2 (if it is necessary
to continue moisture absorption, determine the moisture absorption time, for example, 24 h)
and 6.3. Repeat the weighing of the specimens of moisture absorption.
NOTE: in order to reduce the influence of the volatility of the specimens in the air, the weighing
time shall be shortened as much as possible.
In accordance with Formula (1), calculate the additional moisture content (see Appendix A for
example information of measured data of two types of test materials). Determine at least three
specimens of moisture absorption and take the average value.
Where,
Wad---the additional moisture content of the specimen in the saturated state by moisture
absorption, expressed in (%);
Mn---the mass of the specimen in the saturated state by moisture absorption, determined in
accordance with Formula (2), expressed in (g);
Mi---the mass of the specimen at the beginning of the moisture absorption test, expressed in (g).
In accordance with Formula (2), determine the saturated state by moisture absorption, record
the mass of the specimen in the saturated state by moisture absorption and use it for the
calculation of the saturated moisture content.
Where,
Wn+1---the additional moisture content of the specimen at the (n+1)th test point, expressed in (%);
Wn---the additional moisture content of the specimen at the nth test point, expressed in (%).
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