In which specific devices is Opto-Electronics Glass used as a core material?

As a touch screen panel glass, Opto-Electronics Glass provides high light transmittance and sensitive touch response, while supporting high-resolution display. The flexible characteristics of Opto-Electronics Glass make it suitable for curved screens and thin and light designs, improving the durability and aesthetics of the equipment.

As a display panel, Opto-Electronics Glass supports touch operation and multimedia functions, and has anti-reflection and anti-fingerprint properties to improve driving safety. The high light transmittance and optical properties of Opto-Electronics Glass make it an ideal material for HUD, which can project driving information onto the windshield to reduce the driver's line of sight.

As a display panel for industrial control equipment, Opto-Electronics Glass supports high-brightness display and resistance to harsh environments, and is suitable for factory automation and industrial monitoring systems. The high-precision touch and antibacterial properties of Opto-Electronics Glass make it suitable for medical equipment, such as operating room monitoring terminals and medical imaging equipment.

Opto-Electronics Glass can adjust the light transmittance through electric current to achieve energy saving and privacy protection functions, and is widely used in building curtain walls and smart home systems. As a control panel for smart devices, Opto-Electronics Glass supports touch and voice interaction to enhance the home automation experience.

Photoelectric glass embeds LED chips into glass to achieve a transparent display effect, and is widely used in advertising displays in shopping malls, airports, and subway stations. The high brightness and high contrast characteristics of photoelectric glass make it an ideal material for digital signage and support dynamic content display. Photoelectric glass combines photovoltaic technology to convert solar energy into electrical energy and is applied to photovoltaic building integrated (BIPV) systems to achieve energy self-sufficiency.

The high strength and impact resistance of photoelectric glass make it suitable for instrument panels and helmet displays of aerospace vehicles to provide clear flight information. The high temperature resistance and radiation protection characteristics of photoelectric glass make it an ideal material for military equipment display screens and suitable for combat command in harsh environments.

While maintaining high light transmittance, photoelectric glass supports touch and display functions to enhance user experience. By adjusting the light transmittance, photoelectric glass can reduce indoor lighting energy consumption and meet green building standards. Photoelectric glass has high strength and impact resistance, and is suitable for harsh environments and scenes with high safety requirements. Photoelectric glass can integrate multiple functions such as touch, display, dimming and photovoltaics to meet different application requirements.