Novel Reaction Kinetic Model for Anionic Polyamide-6

Semi‐adiabatic temperature measurements are recorded and used to define semi‐empirical equations for the simulation and prediction of the anionic polyamide‐6 (APA‐6) reaction kinetics. The resin mixture used has a long infusion window before the reaction starts. The prediction of the induction time...

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Published in	Macromolecular materials and engineering Vol. 298; no. 2; pp. 163 - 173
Main Authors	Teuwen, Julie J. E., van Geenen, Ab A., Bersee, Harald E. N.
Format	Journal Article
Language	English
Published	Weinheim WILEY-VCH Verlag 01.02.2013 WILEY‐VCH Verlag Wiley John Wiley & Sons, Inc
Subjects	activation energy anionic polymerization Applied sciences Crystallization Exact sciences and technology Infusion Kinetics kinetics (polym.) Mathematical analysis Mathematical models Organic polymers Physicochemistry of polymers polyamides Polymerization Polymers Preparation, kinetics, thermodynamics, mechanism and catalysts Reaction kinetics Resins Studies Thermosetting resins Ring opening polymerization Amide 6 polymer Kinetic model Bulk polymerization polyamides Anionic polymerization Semiempirical method kinetics (polym.) Experimental study Activation energy Modeling Chemical reaction kinetics
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ISSN	1438-7492 1439-2054
DOI	10.1002/mame.201100457

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Abstract	Semi‐adiabatic temperature measurements are recorded and used to define semi‐empirical equations for the simulation and prediction of the anionic polyamide‐6 (APA‐6) reaction kinetics. The resin mixture used has a long infusion window before the reaction starts. The prediction of the induction time and its corresponding initial temperature of reaction is explored. By means of this semi‐empirical approach and an optimised fitting procedure, the reaction kinetics of APA‐6 can successfully be described. The adiabatic polymerisation can be predicted on the basis of an autocatalytic Kamal‐Sourour model for thermoset resins, and the crystallisation can be described using the isothermal crystallisation model. The reaction kinetics of APA‐6 is successfully described by introducing a new kinetic equation providing a more predictable way of describing the kinetics of this autocatalytic system. The resin mixture used has a long infusion window before reaction starts. Equations are defined for the prediction of the infusion window, i.e., induction time and the corresponding initial temperature of reaction.
AbstractList	Semi-adiabatic temperature measurements are recorded and used to define semi-empirical equations for the simulation and prediction of the anionic polyamide-6 (APA-6) reaction kinetics. The resin mixture used has a long infusion window before the reaction starts. The prediction of the induction time and its corresponding initial temperature of reaction is explored. By means of this semi-empirical approach and an optimised fitting procedure, the reaction kinetics of APA-6 can successfully be described. The adiabatic polymerisation can be predicted on the basis of an autocatalytic Kamal-Sourour model for thermoset resins, and the crystallisation can be described using the isothermal crystallisation model. The reaction kinetics of APA-6 is successfully described by introducing a new kinetic equation providing a more predictable way of describing the kinetics of this autocatalytic system. The resin mixture used has a long infusion window before reaction starts. Equations are defined for the prediction of the infusion window, i.e., induction time and the corresponding initial temperature of reaction. Semi-adiabatic temperature measurements are recorded and used to define semi-empirical equations for the simulation and prediction of the anionic polyamide-6 (APA-6) reaction kinetics. The resin mixture used has a long infusion window before the reaction starts. The prediction of the induction time and its corresponding initial temperature of reaction is explored. By means of this semi-empirical approach and an optimised fitting procedure, the reaction kinetics of APA-6 can successfully be described. The adiabatic polymerisation can be predicted on the basis of an autocatalytic Kamal-Sourour model for thermoset resins, and the crystallisation can be described using the isothermal crystallisation model. [PUBLICATION ABSTRACT] Semi‐adiabatic temperature measurements are recorded and used to define semi‐empirical equations for the simulation and prediction of the anionic polyamide‐6 (APA‐6) reaction kinetics. The resin mixture used has a long infusion window before the reaction starts. The prediction of the induction time and its corresponding initial temperature of reaction is explored. By means of this semi‐empirical approach and an optimised fitting procedure, the reaction kinetics of APA‐6 can successfully be described. The adiabatic polymerisation can be predicted on the basis of an autocatalytic Kamal‐Sourour model for thermoset resins, and the crystallisation can be described using the isothermal crystallisation model. magnified image Semi‐adiabatic temperature measurements are recorded and used to define semi‐empirical equations for the simulation and prediction of the anionic polyamide‐6 (APA‐6) reaction kinetics. The resin mixture used has a long infusion window before the reaction starts. The prediction of the induction time and its corresponding initial temperature of reaction is explored. By means of this semi‐empirical approach and an optimised fitting procedure, the reaction kinetics of APA‐6 can successfully be described. The adiabatic polymerisation can be predicted on the basis of an autocatalytic Kamal‐Sourour model for thermoset resins, and the crystallisation can be described using the isothermal crystallisation model. The reaction kinetics of APA‐6 is successfully described by introducing a new kinetic equation providing a more predictable way of describing the kinetics of this autocatalytic system. The resin mixture used has a long infusion window before reaction starts. Equations are defined for the prediction of the infusion window, i.e., induction time and the corresponding initial temperature of reaction.
Author	Bersee, Harald E. N. van Geenen, Ab A. Teuwen, Julie J. E.
Author_xml	– sequence: 1 givenname: Julie J. E. surname: Teuwen fullname: Teuwen, Julie J. E. email: jjeteuwen@gmail.com organization: Delft University of Technology, Faculty of Aerospace Engineering, Design and Production of Composite Structures, Kluyverweg 1, 2629HS Delft, The Netherlands – sequence: 2 givenname: Ab A. surname: van Geenen fullname: van Geenen, Ab A. organization: Delft University of Technology, Faculty of Aerospace Engineering, Design and Production of Composite Structures, Kluyverweg 1, 2629HS Delft, The Netherlands – sequence: 3 givenname: Harald E. N. surname: Bersee fullname: Bersee, Harald E. N. organization: Delft University of Technology, Faculty of Aerospace Engineering, Design and Production of Composite Structures, Kluyverweg 1, 2629HS Delft, The Netherlands
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Keywords	Ring opening polymerization Amide 6 polymer Kinetic model Bulk polymerization polyamides Anionic polymerization Semiempirical method kinetics (polym.) Experimental study Activation energy Modeling Chemical reaction kinetics
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Snippet	Semi‐adiabatic temperature measurements are recorded and used to define semi‐empirical equations for the simulation and prediction of the anionic polyamide‐6... Semi-adiabatic temperature measurements are recorded and used to define semi-empirical equations for the simulation and prediction of the anionic polyamide-6...
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SubjectTerms	activation energy anionic polymerization Applied sciences Crystallization Exact sciences and technology Infusion Kinetics kinetics (polym.) Mathematical analysis Mathematical models Organic polymers Physicochemistry of polymers polyamides Polymerization Polymers Preparation, kinetics, thermodynamics, mechanism and catalysts Reaction kinetics Resins Studies Thermosetting resins
Title	Novel Reaction Kinetic Model for Anionic Polyamide-6
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