350 rub
Journal Science Intensive Technologies №7 for 2022 г.
Article in number:
Quality control of production of reflecting plates for composite antennas
Type of article: scientific article
DOI: https://doi.org/10.18127/j19998465-202207-01
UDC: 621.396.67
Authors:

M.A. Nazarenko1, D.A. Maliev2

1,2 MIREA – Russian University of Technology (Moscow, Russia)

Abstract:

Polymer composites (PCs) are popular worldwide in the military, civilian and space industries. Methods for adopting polymer composite material (PCM) include autoclaving technology used for large and complex products and non-autoclaving technology used to produce small quantities. PCMs are not yet well known and are therefore used in high risk and demanding products. Therefore, the product quality assurance process should include the management and monitoring of non-conformities at all stages of production.

Purpose. Consider the parameters required to monitor and control the manufacturing process of reflective plates for composite antennas throughout the PCM manufacturing process.

Parameters, characteristics and results for the most effective quality control in production of composite antennas are considered. A list of quality assurance measures for antennas using polymer composites is provided. The basic quality requirements for reflector production are also described. The main requirements of international quality assurance are listed. All versions of the ISO 9000 standard are considered and the basic concepts of quality assurance of composite antennas are mentioned. The main parameters in the production of PCM products are the product temperature, heating rate and pressing time.

By finding the parameters, characteristics and results for the most effective quality control in the production of composite antennas, it is possible to improve their quality in the future.

Pages: 5-9
For citation

Nazarenko M.A., Maliev D.A. Quality control of production of reflecting plates for composite antennas. Science Intensive Technologies. 2022. V. 23. № 7. P. 5−9. DOI: https://doi.org/10.18127/j19998465-202207-01 (in Russian)

References
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Date of receipt: 20.04.2022
Approved after review: 29.04.2022
Accepted for publication: 20.09.2022