Kapasite Değerini Artırmak İçin Yeni Paralel Plakalı Kondansatör Tasarımı

Year 2019, Volume: 7 Issue: 1, 168 - 173, 15.01.2019

Turgut Ozturk

https://doi.org/10.21541/apjes.424663

Cited By: 1

Abstract

Enerji depolama sistemleri; medikal, savunma, askeri, telekomünikasyon ve havacılık uygulamaları gibi pek çok alanda önemli bir yere sahip olduğundan, dielektrik malzemelere olan talep hızla artmıştır. Elektromanyetik dalgaların madde ile etkileşimi, depolanmış enerji hakkında önemli bilgiler sağlar. Bu nedenle, enerji depolama kapasitesini dielektrik malzemeye borçlu olan enerji uygulamalarının bir örneği olarak kapasitör, kapasite değerinin dielektrik sabiti ve farklı tasarım üzerindeki bağımlılığını göstermek için Ansys Maxwell benzetim programı kullanılarak tasarlanmıştır. Enerji depolama kapasitesi ve farklı tasarım arasındaki ilişki, paralel plaka ve çok katmanlı modeller olan farklı yapılar kullanılarak gösterilmiştir. Ayrıca, kapasitörün kapasitans değerinin arttırılması için yeni bir model tasarlanıp analiz edilmiştir. Bu işlem ile dielektrik malzemenin yüzey alanı ile iletken boru / tel arasındaki etkileşimin artırılması amaçlanmıştır.

Keywords

Ansys maxwell, karmaşık elektriksel geçirgenlik, kapasitör tasarımı, dielektrik malzemeler, enerji

Design of a New Parallel-Plate Capacitor to Increase the Capacity Value

Abstract

The demand for dielectric materials has increased
rapidly since the energy storage systems have an important place in many areas
such as medical, defense, military, telecommunication and aerospace
applications. The interaction of the electromagnetic waves with matter provides
valuable information about the stored energy by material. Hence, the capacitor
as an example of energy applications, which owes its energy storage capability
to the internal dielectric material, is designed by using Ansys Maxwell
software program to indicate the dependence of the capacitance on the dielectric
constant and different design. The relationship between energy storage capacity
and different design is shown by using different structures which are parallel
plate and multi layered models. Furthermore, a new model has been designed and analyzed
to increase the performance of capacitance value of capacitor. It is aimed to
increase the interaction between surface area of dielectric material and
conductive pipes/wires with this operation.

Keywords

Ansys maxwell, complex permittivity, capacitor design, dielectric materials, energy

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