Investigation on promotion effect of oxidative stabilization for pitch‐based fiber by co‐carbonization of coal tar pitch and atmospheric residual

Investigation on promotion effect of oxidative stabilization for pitch‐based fiber by co‐carbonization of coal tar pitch and atmospheric residual

As a pivotal step in the preparation of carbon fiber, oxidative stabilization not only plays a crucial role in maintaining fibrous morphology but also contributes significantly to enhance mechanical properties of resultant carbon fiber. Due to high activation energy of pitch molecules reaction with...

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Veröffentlicht in:Journal of applied polymer science 2024-04, Vol.141 (15), p.n/a
Hauptverfasser: Niu, Hao, Miao, Guihua, Shen, Wenzhong, Qu, Shijie
Format: Artikel
Sprache:eng
Schlagworte:
Aliphatic compounds
aliphatic structure
Carbon fibers
Carbonization
Coal tar
isotropic spinnable pitch
Mechanical properties
Modulus of elasticity
Molecular structure
oxidative stabilization efficiency
Oxygen
Pitch (material)
pitch‐based carbon fiber
Stabilization
Tensile strength
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Miao, Guihua
Shen, Wenzhong
Qu, Shijie
description As a pivotal step in the preparation of carbon fiber, oxidative stabilization not only plays a crucial role in maintaining fibrous morphology but also contributes significantly to enhance mechanical properties of resultant carbon fiber. Due to high activation energy of pitch molecules reaction with oxygen and the sluggish diffusion of oxygen within the fiber, the improvement of oxidative stabilization efficiency faces significant challenges. Atmospheric residual (AR) has a high and easily oxidized aliphatic structure. Spinnable pitch is synthesized by co‐carbonization of coal tar pitch (CTP) and AR at a ratio of 3:1 in this work. Its methylene bridge bond ratio is 4.45% and have an appropriate amount aliphatic structure, which makes pitch molecular more linear and naphthenic. Excessive addition of AR is detrimental to spinning performance. The most optimal oxidative stabilization temperature of as‐spun fiber was 280°C, which is lower than that of fiber produced by CTP alone (300°C), displaying a higher oxidative stabilization efficiency. The obtained pitch‐based carbon fiber shows excellent mechanical properties with tensile strength of 999.0 ± 80.1 MPa and Young's modulus of 57.7 ± 3.5 GPa. The co‐carbonization by two different substances has been applied in manufacturing carbon fiber, providing a facile approach to accelerate the oxidative stabilization of pitch fiber. The introduction of aliphatic structure by co‐carbonization of coal tar pitch and atmospheric residual provides more methylene bridge bonds and more α‐hydrogens for spinnable pitch, which makes pitch molecular more linear and naphthenic. The α‐hydrogens of aliphatic structure of the CCA‐3 are easily attacked by oxygen, showing a higher oxidative stabilization efficiency. The obtained pitch‐based carbon fiber shows excellent mechanical properties.
doi_str_mv 10.1002/app.55207
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Due to high activation energy of pitch molecules reaction with oxygen and the sluggish diffusion of oxygen within the fiber, the improvement of oxidative stabilization efficiency faces significant challenges. Atmospheric residual (AR) has a high and easily oxidized aliphatic structure. Spinnable pitch is synthesized by co‐carbonization of coal tar pitch (CTP) and AR at a ratio of 3:1 in this work. Its methylene bridge bond ratio is 4.45% and have an appropriate amount aliphatic structure, which makes pitch molecular more linear and naphthenic. Excessive addition of AR is detrimental to spinning performance. The most optimal oxidative stabilization temperature of as‐spun fiber was 280°C, which is lower than that of fiber produced by CTP alone (300°C), displaying a higher oxidative stabilization efficiency. The obtained pitch‐based carbon fiber shows excellent mechanical properties with tensile strength of 999.0 ± 80.1 MPa and Young's modulus of 57.7 ± 3.5 GPa. 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Due to high activation energy of pitch molecules reaction with oxygen and the sluggish diffusion of oxygen within the fiber, the improvement of oxidative stabilization efficiency faces significant challenges. Atmospheric residual (AR) has a high and easily oxidized aliphatic structure. Spinnable pitch is synthesized by co‐carbonization of coal tar pitch (CTP) and AR at a ratio of 3:1 in this work. Its methylene bridge bond ratio is 4.45% and have an appropriate amount aliphatic structure, which makes pitch molecular more linear and naphthenic. Excessive addition of AR is detrimental to spinning performance. The most optimal oxidative stabilization temperature of as‐spun fiber was 280°C, which is lower than that of fiber produced by CTP alone (300°C), displaying a higher oxidative stabilization efficiency. The obtained pitch‐based carbon fiber shows excellent mechanical properties with tensile strength of 999.0 ± 80.1 MPa and Young's modulus of 57.7 ± 3.5 GPa. The co‐carbonization by two different substances has been applied in manufacturing carbon fiber, providing a facile approach to accelerate the oxidative stabilization of pitch fiber. The introduction of aliphatic structure by co‐carbonization of coal tar pitch and atmospheric residual provides more methylene bridge bonds and more α‐hydrogens for spinnable pitch, which makes pitch molecular more linear and naphthenic. The α‐hydrogens of aliphatic structure of the CCA‐3 are easily attacked by oxygen, showing a higher oxidative stabilization efficiency. The obtained pitch‐based carbon fiber shows excellent mechanical properties.</abstract><cop>Hoboken, USA</cop><pub>John Wiley &amp; Sons, Inc</pub><doi>10.1002/app.55207</doi><tpages>15</tpages><orcidid>https://orcid.org/0009-0008-6291-6731</orcidid></addata></record>
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source Wiley Online Library Journals Frontfile Complete
subjects Aliphatic compounds
aliphatic structure
Carbon fibers
Carbonization
Coal tar
isotropic spinnable pitch
Mechanical properties
Modulus of elasticity
Molecular structure
oxidative stabilization efficiency
Oxygen
Pitch (material)
pitch‐based carbon fiber
Stabilization
Tensile strength
title Investigation on promotion effect of oxidative stabilization for pitch‐based fiber by co‐carbonization of coal tar pitch and atmospheric residual
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