The light transmittance of silicone bipv glass floor is closely related to its unique material combination. As a composite product that combines silicone materials and photovoltaic modules, it uses high-transmittance glass as the substrate, and the silicone coating further optimizes the light transmission performance. This material combination allows natural light to pass through the floor smoothly, providing sufficient light for the space below, while also creating conditions for the photovoltaic modules to absorb light energy, achieving a preliminary balance between light transmission and light absorption.
In terms of ensuring lighting below, the light transmission design of silicone bipv glass floor is quite ingenious. Its glass layer has been specially treated, and its light transmittance is higher than that of ordinary glass, allowing more natural light to penetrate into the area below. Whether it is the ground floor space of an office building or the underground area of a shopping mall, this floor can help to obtain a brighter environment and reduce dependence on artificial lighting. Even on cloudy days, the scattered light through the floor can keep the space below at a certain brightness and improve the comfort of the space.
The core of efficient absorption of light energy lies in the synergy between photovoltaic modules and light transmission design. The photovoltaic cells inside the floor adopt a translucent design, which allows some light to pass through while accurately capturing sunlight of a specific wavelength for energy conversion. The optical properties of silicone materials help focus light, allowing more light energy to be concentrated on photovoltaic cells, reducing light waste. This "light-transmitting and light-absorbing" design allows the floor to ensure lighting below without sacrificing light energy absorption efficiency.
Under different light conditions, the light transmission and light absorption performance of silicone bipv glass floor can remain stable. In a strong light environment, it will not cause overexposure of the lighting below due to excessive light, but by adjusting the light transmittance, the light below is soft and not glaring, and the photovoltaic components efficiently absorb strong light and convert it into electrical energy; in a weak light environment, its light transmittance is relatively improved to ensure the lighting needs below, and the photovoltaic components can also capture weak light for energy conversion, adapting to light changes in different weather and time periods.
Silicone coating plays a key role in improving light transmission and light absorption performance. This coating has good light transmittance and will not hinder light from passing through the glass. At the same time, it can reduce the reflection loss of light on the glass surface, allowing more light to enter the floor - part of it passes through the floor to the bottom, and part of it is absorbed by the photovoltaic components. In addition, the silicone coating has strong weather resistance, and the light transmittance will not decrease due to aging after long-term use, ensuring the long-term stability of light transmission and light absorption performance.
For places that need to take into account both lighting and power generation, the advantages of this glass floor are particularly obvious. For example, in areas such as atriums and corridors, after laying silicone bipv glass floors, natural light from above can illuminate the space below, reducing lighting energy consumption, while the floor's own power generation can be used for surrounding equipment, realizing the cascade utilization of energy. This "kill two birds with one stone" effect is a direct reflection of its optimized design of light transmission and light absorption performance.
The silicone bipv glass floor has good light transmission and can efficiently absorb light energy while ensuring lighting below. The combination of high light transmittance substrate and silicone coating, the translucent design of photovoltaic modules, and the adaptability to different light conditions have made it find a perfect balance between light transmission and light absorption. Whether it is to provide natural lighting for the space below or to capture light energy for its own power generation system, it can complete the task excellently and become a new building material that is both practical and energy-saving.
