High-speed detection of human skin and breath! Visualizing "heat" to catch abnormal phenomena in 0.01 seconds.
"TL-SENSING" is a thermal flux sensor developed by the University of Tokyo that aims to solve global thermal challenges with topological materials. It features a thin film structure that is 1/1000 the size of conventional sensors, allowing for high shape flexibility. This product is expected to be utilized in various applications, including abnormal detection and failure prediction for batteries and power semiconductor components, as well as devices for controlling thermal comfort in body temperature, vehicles, and indoor environments. [Features] - Detects minute heat levels at breath level in just 0.01 seconds - Thin film structure that is 1/1000 the size of conventional sensors - High shape flexibility - Cost-effective mass production *For more details, please refer to the PDF document or feel free to contact us.
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【Specifications】 ■Dimensions ・Substrate: 20×20×0.5mm ・Element Circuit: Meander Structure ■Thermoelectric Performance: 0.2μV/W/m2 ■Time Constant: Less than 0.01 seconds ■Materials (Sputtering) ・MgO Substrate: t0.5mm ・Topological Material: t100nm ・Surface Protection: Kapton Tape *For more details, please refer to the PDF document or feel free to contact us.
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【Applications】 ■ Abnormal detection and failure prediction of batteries and power semiconductor components ■ Body temperature and thermal comfort control devices for vehicles and indoor environments ■ Chemical sensors and gas sensors combining reaction catalysts and light-absorbing films ■ Thermal management, control, and monitoring in factories and production sites ■ Human body monitoring, etc. *For more details, please refer to the PDF document or feel free to contact us.
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Our company was established with the aim of implementing new materials based on quantum science that exhibit unique properties known as "topological materials" into society. By implementing energy visualization, energy conservation, and utilization technologies that were not achievable with conventional materials, we promote QX (Quantum Transformation) and aim to surpass the limits of effective energy use, striving for the sustainable realization of a prosperous society.