{"title":"太阳能电池板作为微型固定翼无人机充电系统的使用效果","authors":"I. Ridwan, Alfindo","doi":"10.1063/1.5135553","DOIUrl":null,"url":null,"abstract":"Unmanned Aerial Vehicle (UAV), popularly known as drone, is a type of aerial explorer robot that can be controlled remotely to carry out certain missions. One type of UAV for carrying out a flying mission is a fixed-wing type. It is widely used for mapping and monitoring equipment. This type of drone has limited flight time because the battery used has limited capacity, especially in micro scale UAVs with±2 kg weight. Therefore, sometimes the drone must return to replace the battery before the mission is complete. In this condition, experimental research is needed with the addition of solar panels in the wings to increase flight time. The method used to solve this problem is by designing an electronic component UAV which is integrated with a solar panel charger system, an airframe with 2.125 kg flight weight, 18 m/s cruise speed, 1.63 m wingspan, and 0.37 m2 wing surface area. The solar cells used are Sunpower C60, are arranged in series of 10 pieces with 21% maximum efficiency and 0.132 m2 total surface area. The solar panel charger system is integrated with UAV electronic components that use the Tarot2814 brushless motor with 290 W maximum power, ESC 30 A, 4S Sony VTC6 3000 mAh battery, LM2587 5A step-up module, and Arduino solar charge controller. The results of the research prove that micro scale UAV-Solar can add flight time for 2 minutes with an intensity of solar radiation average of 929.46 W/m2. During flight testing, solar cells produce an average power of 15.14 W with a maximum efficiency of 14.8% and a total flight time of 15 minutes. This proves that the addition of solar panels to UAV micro scale fixed wing types can be realized.Unmanned Aerial Vehicle (UAV), popularly known as drone, is a type of aerial explorer robot that can be controlled remotely to carry out certain missions. One type of UAV for carrying out a flying mission is a fixed-wing type. It is widely used for mapping and monitoring equipment. This type of drone has limited flight time because the battery used has limited capacity, especially in micro scale UAVs with±2 kg weight. Therefore, sometimes the drone must return to replace the battery before the mission is complete. In this condition, experimental research is needed with the addition of solar panels in the wings to increase flight time. The method used to solve this problem is by designing an electronic component UAV which is integrated with a solar panel charger system, an airframe with 2.125 kg flight weight, 18 m/s cruise speed, 1.63 m wingspan, and 0.37 m2 wing surface area. 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引用次数: 5

摘要

无人驾驶飞行器(UAV),俗称无人机,是一种可以远程控制执行某些任务的空中探测机器人。一种用于执行飞行任务的无人机是固定翼型。广泛用于测绘和监测设备。这种类型的无人机飞行时间有限,因为使用的电池容量有限,特别是在±2公斤重量的微型无人机中。因此,有时无人机必须在任务完成之前返回更换电池。在这种情况下,需要进行实验研究,在机翼上增加太阳能电池板以增加飞行时间。解决这一问题的方法是设计一种集成了太阳能电池板充电系统的电子组件无人机,机身飞行重量2.125 kg,巡航速度18 m/s,翼展1.63 m,翼表面积0.37 m2。所使用的太阳能电池是Sunpower C60,由10片组成,最高效率为21%,总表面积为0.132平方米。太阳能电池板充电系统集成了无人机电子元件,使用最大功率290 W的Tarot2814无刷电机,ESC 30a, 4S索尼VTC6 3000mah电池,LM2587 5A升压模块和Arduino太阳能充电控制器。研究结果表明,微尺度无人机-太阳能可以在平均太阳辐射强度为929.46 W/m2的情况下增加2分钟的飞行时间。在飞行测试中,太阳能电池产生的平均功率为15.14 W,最高效率为14.8%,总飞行时间为15分钟。这证明了微型固定翼型无人机增加太阳能板是可以实现的。无人驾驶飞行器(UAV),俗称无人机,是一种可以远程控制执行某些任务的空中探测机器人。一种用于执行飞行任务的无人机是固定翼型。广泛用于测绘和监测设备。这种类型的无人机飞行时间有限,因为使用的电池容量有限,特别是在±2公斤重量的微型无人机中。因此,有时无人机必须在任务完成之前返回更换电池。在这种情况下,需要进行实验研究,在机翼上增加太阳能电池板以增加飞行时间。解决这一问题的方法是设计一种集成了太阳能电池板充电系统的电子组件无人机,机身飞行重量2.125 kg,巡航速度18 m/s,翼展1.63 m,翼表面积0.37 m2。使用的太阳能电池是Sunpower C60,以10片串联排列,最高效率为21%,总表面积为0.132平方米。
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The effect of use of solar panels on micro scale fixed-wing UAV type as a power recharging system
Unmanned Aerial Vehicle (UAV), popularly known as drone, is a type of aerial explorer robot that can be controlled remotely to carry out certain missions. One type of UAV for carrying out a flying mission is a fixed-wing type. It is widely used for mapping and monitoring equipment. This type of drone has limited flight time because the battery used has limited capacity, especially in micro scale UAVs with±2 kg weight. Therefore, sometimes the drone must return to replace the battery before the mission is complete. In this condition, experimental research is needed with the addition of solar panels in the wings to increase flight time. The method used to solve this problem is by designing an electronic component UAV which is integrated with a solar panel charger system, an airframe with 2.125 kg flight weight, 18 m/s cruise speed, 1.63 m wingspan, and 0.37 m2 wing surface area. The solar cells used are Sunpower C60, are arranged in series of 10 pieces with 21% maximum efficiency and 0.132 m2 total surface area. The solar panel charger system is integrated with UAV electronic components that use the Tarot2814 brushless motor with 290 W maximum power, ESC 30 A, 4S Sony VTC6 3000 mAh battery, LM2587 5A step-up module, and Arduino solar charge controller. The results of the research prove that micro scale UAV-Solar can add flight time for 2 minutes with an intensity of solar radiation average of 929.46 W/m2. During flight testing, solar cells produce an average power of 15.14 W with a maximum efficiency of 14.8% and a total flight time of 15 minutes. This proves that the addition of solar panels to UAV micro scale fixed wing types can be realized.Unmanned Aerial Vehicle (UAV), popularly known as drone, is a type of aerial explorer robot that can be controlled remotely to carry out certain missions. One type of UAV for carrying out a flying mission is a fixed-wing type. It is widely used for mapping and monitoring equipment. This type of drone has limited flight time because the battery used has limited capacity, especially in micro scale UAVs with±2 kg weight. Therefore, sometimes the drone must return to replace the battery before the mission is complete. In this condition, experimental research is needed with the addition of solar panels in the wings to increase flight time. The method used to solve this problem is by designing an electronic component UAV which is integrated with a solar panel charger system, an airframe with 2.125 kg flight weight, 18 m/s cruise speed, 1.63 m wingspan, and 0.37 m2 wing surface area. The solar cells used are Sunpower C60, are arranged in series of 10 pieces with 21% maximum efficiency and 0.132 m2 total surface ...
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