Study on Screen Printable Color Paste Formulation for Color Silicon Solar Modules

UTOMO, BENNY PUTRA and Anggono, Juliana and Shin, Dong Youn (2022) Study on Screen Printable Color Paste Formulation for Color Silicon Solar Modules. Journal of the Korean Solar Energy Society, 42 (4). pp. 1-14. ISSN 1598-6411

[thumbnail of Publikasi1_94016_9405.pdf] PDF
Publikasi1_94016_9405.pdf

Download (1MB)
[thumbnail of Publikasi4_94016_9405.pdf] PDF
Publikasi4_94016_9405.pdf

Download (3MB)
[thumbnail of paper - Juliana]
Preview
PDF (paper - Juliana)
Study_on_Screen_Printable_Color_-_PAPER.pdf

Download (2MB)
[thumbnail of cek plagiasi - Juliana]
Preview
PDF (cek plagiasi - Juliana)
Study_on_Screen_Printable_Color_-_CP.pdf

Download (3MB)
[thumbnail of korespondensi - Juliana]
Preview
PDF (korespondensi - Juliana)
Study_on_Screen_Printable_-_KORESPONDENSI.pdf

Download (423kB)

Abstract

Photovoltaic (PV) modules are incorporated into buildings as constitutional elements in building integrated PVs (BIPVs). BIPVs are evident in daily life as various forms on the roofs or skins of buildings. However, their mediocre color (typically black), has led to poor public acceptance. The development of color BIPVs is required to bestow aesthetic value to buildings.
Coloring has been primarily achieved using expensive vacuum deposition processes. However,
screen printing is becoming widely recognized as a highly competitive manufacturing technique
for the fabrication of color BIPVs. Superior characteristics of screen printing include low cost,
simplicity, and scalability. In this study, the formulation of color pastes using light interference pigments for screen printing is explored, because the success of screen-printed color BIPVs
primarily depends on printability of these pastes. The screen printability of color pastes based on a commercially available two-part liquid paste and an in-house developed carrier vehicle was evaluated. The relativePV conversion efficiency of a color silicon solar module was 90% compared to a reference silicon solar module.

Item Type: Article
Uncontrolled Keywords: Color silicon solar module, Screen printing, Light interference pigment, Color paste
Subjects: T Technology > TJ Mechanical engineering and machinery
Divisions: Faculty of Industrial Technology > Mechanical Engineering Department
Depositing User: Admin
Date Deposited: 13 Jul 2023 00:20
Last Modified: 18 Jul 2023 08:04
URI: https://repository.petra.ac.id/id/eprint/20483

Actions (login required)

View Item
View Item