This research was analyzed thermal characteristics that was appointed disadvantage when smart LED driver ICs was packaged and we applied extracted thermal characteristics for optimal layout design. We confirmed reliability of smart LED driver ICs package without additional heat sink. If the package is not heat sink, we are possible to minimize package. For extracting thermal loss due to overshoot current, we increased driver current by two and three times. As a result of experiment, we obtained 22 mW and 49.5 mW thermal loss. And we obtained optimal data of 350 mA driver current. It is important to distance between power MOSFET and driver ICs. If thhe distance was increased, the temperature of package was decreased. And so we obtained optimal data of 3.7 mm distance between power MOSFET and driver ICs. Finally, we fabricated real package and we analyzed the electrical characteristics. We obtained constant 35 V output voltage and 80% efficiency.
This research was analyzed thermal characteristics that was appointed disadvantage when smart LED driver ICs was packaged and we applied extracted thermal characteristics for optimal layout design. We confirmed reliability of smart LED driver ICs package without additional heat sink. If the package is not heat sink, we are possible to minimize package. For extracting thermal loss due to overshoot current, we increased driver current by two and three times. As a result of experiment, we obtained 22 mW and 49.5 mW thermal loss. And we obtained optimal data of 350 mA driver current. It is important to distance between power MOSFET and driver ICs. If thhe distance was increased, the temperature of package was decreased. And so we obtained optimal data of 3.7 mm distance between power MOSFET and driver ICs. Finally, we fabricated real package and we analyzed the electrical characteristics. We obtained constant 35 V output voltage and 80% efficiency.
Thermal batteries are primary reserve batteries that use inorganic salt as electrolytes which areinactive at room temperature. The two principal heat sources that have been used in thermal batteries areheat paper and heat pellets. As soon as the heat paper, which is ignited by the initiator, in turn ignites theheat pellets, all the solid electrolytes are melted into excellent ionic conductors. However, the highcombustion temperature by heat papers in thermal batteries causes thermal decomposition at the cathode,eventually leading to a thermal runaway. In this paper, we have attempted to prepare Zr/BaCrO4 heatpapers coated with KCl molten salt. We have also investigated the effect of a molten salt coating on theheat papers through the thermal characteristics such as calorimetric value, combustion temperature andburning rate. The calorimetric value and combustion temperature of heat papers were reduced with anincrease in the molten salt coating. As a result, the molten salt coating on heat papers greatly reducedrisk of a thermal runaway and improved the stability of thermal batteries.