๊ธ€ ์ฐพ๊ธฐ
์‹ค๋ž€ ๊ธฐ๋Šฅ์„ฑ ์ฒจ๊ฐ€์ œ๋Š” ํƒœ์–‘๊ด‘ ํ•„๋ฆ„ ์‘์šฉ ๋ถ„์•ผ์—์„œ ๋‚ดํ›„์„ฑ์„ ์–ด๋–ป๊ฒŒ ๊ฐœ์„ ํ•  ์ˆ˜ ์žˆ์„๊นŒ์š”?

Photovoltaic (PV) film durability and long-term performance are significantly influenced by weathering resistance. Exposure to a range of external factors, such as moisture, temperature swings, and UV radiation, can shorten the lifespan of photovoltaic modules. The advent of silane functional additives has brought about a huge revolution in PV film applications by improving weathering resistance. This article highlights the chemical principles, film stability, and industrial applications of silane functional additives, which play a multifaceted role in enhancing weathering resistance from several viewpoints.

Recognizing Functional Additives in Silane

Organic compounds containing silane groups, usually made up of silicon and hydrogen atoms, are known as ์‹ค๋ž€ ๊ธฐ๋Šฅ์„ฑ ์ฒจ๊ฐ€์ œ. PV films can have these chemicals added to the formulation to improve their resistance to weathering. Through a process known as silanization, silane functional additives are able to form covalent bonds with the film matrix thanks to their special chemical characteristics. The film becomes more crosslinked as a result of this chemical reaction, strengthening its stability and resistance to external influences.

 

Increased Resistance to UV

One of the main causes of PV film degradation is UV exposure. Ineffective UV protection has frequently been demonstrated by traditional additives, which has resulted in yellowing, a loss of transparency, and decreased electrical performance. UV light is absorbed and dispersed by a protective layer formed by silane functional additives, providing an answer. These additives’ silane groups engage in photochemical reactions that capture UV photons and transform them into innocuous heat energy. Through the effective reduction of UV radiation, the optical and electrical properties of the PV film are preserved.

์Šต๊ธฐ์— ๋Œ€ํ•œ ๋‚ด์„ฑ ๊ฐ•ํ™”

PV films are susceptible to a variety of negative consequences from moisture penetration, such as delamination, corrosion, and reduced electrical performance. Silane functional additives increase the film’s resistance to moisture by creating a hydrophobic barrier on its surface. These additives’ silane groups react with ambient moisture to form siloxane linkages, which provide a coating that is water-repellent. By keeping out water, this hydrophobic barrier reduces the chance of corrosion and delamination. Furthermore, the decreased absorption of moisture aids in preserving the film’s dimensional stability, guaranteeing steady performance throughout time.

 

Resistance to Oxidation and Thermal Stability

Variations in temperature can cause thermal stress on photovoltaic films, which can result in mechanical deformation and decreased electrical output. Silane functional additives improve the resistance of PV films to oxidation and heat, which in turn contributes to their thermal stability. These additives’ silane groups interact with the film matrix to create a stable network that is resistant to high temperatures. Long-term stability and dependability are ensured by the film’s improved resistance to oxidation and heat degradation due to its crosslinked structure.

Uses in Industry

The PV film business has undergone a revolution with the introduction of silane functional additives, creating new opportunities for a range of applications. These additives improve the weathering resilience of encapsulant films, back sheets, and front sheets, which are commonly employed in the production of solar panels. They are also used in flexible photovoltaic modules, where they extend the lifetime and robustness of thin-film systems. In building-integrated photovoltaics (BIPV), silane functional additives are also used to improve the weathering durability of PV films that are integrated into architectural features.

 

 

 

In solar film applications, silane functional additives have become a potent way to improve weathering resistance. They improve oxidation resistance, moisture resistance, UV resistance, and thermal stability through distinct chemical processes. By adding these compounds, PV films become much more resilient, effective, and long-lasting, which increases their suitability for a range of environmental scenarios. The increasing need for dependable and durable solar energy solutions is anticipated to drive the use of silane functional additives, which will be essential in improving the efficiency and sustainability of photovoltaic technology.

 

 

 

์ตœ๊ทผ ๊ธฐ์‚ฌ

๋‚˜์ผ๋ก  ์ธ์„ฑ ํ–ฅ์ƒ์„ ์œ„ํ•ด ์ ์ ˆํ•œ POE ์ ‘๋ชฉ ๋ฌด์ˆ˜ ๋ง๋ ˆ ์‚ฐ์—ผ์„ ์„ ํƒํ•˜๋Š” ๋ฐฉ๋ฒ•์€ ๋ฌด์—‡์ž…๋‹ˆ๊นŒ?

ํŠนํžˆ ๋ณด๊ฐ• ๋ฐ ์ถฉ์ง„์ด ํ•„์š”ํ•œ PA6, PA66 ๋ฐ ํด๋ฆฌ์•„๋ฏธ๋“œ ์‹œ์Šคํ…œ์„ ์œ„ํ•œ ์ถฉ๊ฒฉ ์™„ํ™”์ œ๋กœ ์„ค๊ณ„๋œ Coaceยฎ W1A-F๋Š” ํŠน๋ณ„ํ•œ ํŠน์„ฑ์œผ๋กœ ์ธํ•ด ํ–ฅ์ƒ๋œ ๋‚ด์ถฉ๊ฒฉ์„ฑ๊ณผ ์ธ์„ฑ์ด ๊ฐ€์žฅ ์ค‘์š”ํ•œ ์šฉ๋„์— ์™„๋ฒฝํ•œ ์„ ํƒ์ด ๋  ์ˆ˜ ์žˆ์Šต๋‹ˆ๋‹ค.

์ž์„ธํžˆ ๋ณด๊ธฐ โ†’

PBT ๊ฐœ์งˆ์˜ ์ƒˆ๋กœ์šด ๋ŒํŒŒ๊ตฌ: POE-g-GMA ๊ฐ•ํ™”์ œ์˜ ํ˜์‹ ์ ์ธ ์ ์šฉ

PBT ๊ฐœ์งˆ์— POE-g-GMA ๊ฐ•ํ™”์ œ๋ฅผ ์‚ฌ์šฉํ•˜๋ฉด PBT ์†Œ์žฌ์˜ ์ทจ์„ฑ์„ ํ•ด๊ฒฐํ•  ๋ฟ๋งŒ ์•„๋‹ˆ๋ผ ์ƒˆ๋กœ์šด ํ”Œ๋ผ์Šคํ‹ฑ ์‚ฐ์—… ๋ฐœ์ „ ๋ฐฉํ–ฅ์„ ์ œ์‹œํ•  ์ˆ˜ ์žˆ์Šต๋‹ˆ๋‹ค.

์ž์„ธํžˆ ๋ณด๊ธฐ โ†’

PP/PE ๋ณตํ•ฉ ์†Œ์žฌ์— ํ•„๋Ÿฌ๋ฅผ ์ถ”๊ฐ€ํ•  ๋•Œ ํ˜ธํ™˜์ œ๋ฅผ ์ถ”๊ฐ€ํ•ด์•ผ ํ•˜๋‚˜์š”?

PP-g-MAH ํ˜ธํ™˜์ œ์˜ ์‚ฌ์šฉ๋ฒ•์„ ์กฐ์‚ฌํ•˜๊ณ  ์‹ถ๋‹ค๋ฉด ์ „๋ฌธ ํ™”ํ•™๋ฌผ์งˆ ๊ณต๊ธ‰์—…์ฒด์— ๋ฌธ์˜ํ•˜๋ฉด ์ƒ˜ํ”Œ๊ณผ ๊ธฐ์ˆ  ์ง€์›์„ ๋ฐ›์„ ์ˆ˜ ์žˆ์Šต๋‹ˆ๋‹ค. COACE์™€ ์ƒ๋‹ดํ•˜๋ฉด ํŠน์ • ์• ํ”Œ๋ฆฌ์ผ€์ด์…˜ ์š”๊ตฌ ์‚ฌํ•ญ์„ ์ถฉ์กฑํ•˜๋Š” ๋งž์ถคํ˜• ๋ฏน์Šค๋ฅผ ๋งŒ๋“ค ์ˆ˜ ์žˆ์Šต๋‹ˆ๋‹ค.

์ž์„ธํžˆ ๋ณด๊ธฐ โ†’

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