Improving the Energy Efficiency of Autoclave Equipment by Optimizing the Technology of Manufacturing Parts from Polymer Composite Materials

I.V. Zaychenko; V.V. Bazheryanu; S.A. Gordin

doi:10.4028/www.scientific.net/MSF.992.341

Paper Titles

Studies of Microwave Electromagnetic Field Influence on Adhesion Strength of the “Matrix-Fiber” Contact Zone on the Example of the Elementary Cell of a Certified Polymeric Composite Material
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Studying the Effect of Temperature, Static Load and Nanodimensional Defects on the Mechanical Properties of Polyethylene Film at Uniaxial Extension
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Destruction of Epoxy-Based Composite Materials under the Influence of Impact Load
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Formation of the Structure and Properties of Epoxy-Based Composite Materials
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Improving the Energy Efficiency of Autoclave Equipment by Optimizing the Technology of Manufacturing Parts from Polymer Composite Materials
p.341

Local Repair of Parts from Polymer Composite Material with the Use of Portable Hot Bonder Control Systems
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Investigation of the Effect of Mechanical Activation of Powder Components on the Properties of Polyimide Composites
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About Communication of the Comparative Properties Plasticized PVC Compositions and Quantities of Additives Used
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Thermophysical Properties of Syntactic Foams Based on Polymethylphenylsiloxane Resin and Hollow Glass Microspheres
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HomeMaterials Science ForumMaterials Science Forum Vol. 992Improving the Energy Efficiency of Autoclave...

Improving the Energy Efficiency of Autoclave Equipment by Optimizing the Technology of Manufacturing Parts from Polymer Composite Materials

Abstract:

Autoclaves used for the manufacture of parts from polymer composite materials (PCM) for structural purposes are equipment that consumes a significant amount of energy. In the manufacture of parts of a monolithic design from PCM in 2 transitions in order to reduce energy consumption, it was proposed: during the first molding, reduce the main exposure time, which reduced the operating time of the autoclave tens. In the workpiece, the complete polymerization of the adhesive binder occurs during the second molding transition. Also, it was proposed to manufacture parts of a honeycomb structure from adhesive prepregs for one molding with an autoclave under-molding at an elevated temperature instead of the first molding. The formation of a monolithic zone of honeycomb parts in one cycle eliminated the formation of unacceptable defects: "delamination" and "increased attenuation of the ultrasonic signal." A change in the technology of molding PCM parts has reduced manufacturing time, labor and energy consumption compared to the previously used mode in 2 transitions. The quality of gluing parts according to this advanced technology is confirmed by the results of acoustic control and mechanical tests.

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Periodical:

Materials Science Forum (Volume 992)

Pages:

341-346

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.992.341

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Online since:

May 2020

Authors:

I.V. Zaychenko*, V.V. Bazheryanu, S.A. Gordin

Keywords:

Adhesive Prepreg, Aircraft Manufacturing, Autoclave Molding, Energy Saving, Polymer Composite Materials

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