Modelling Heat Transfer in Solar Distiller with Additional Condenser Studying

Nagham T. Ibraheem, Hazim Hussain, Omar L. Khaleed
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引用次数: 1

Abstract

The sun is the main source of energy that reaches the surface of the earth in the form of electromagnetic radiation called solar radiation and when it reaches the outer surface of the glass hood of the solar distillation, the process of energy transferring as the heat begins. the energy transfer process between parts of solar distillates greatly controls its performance, so the greater amount of energy gained and the less energy lost, leads to higher productivity and efficiency of the solar distillery. in this paper, a mathematical model was constructed to calculate the amount of thermal energy in each part of a monoclinic solar distiller equipped with an additional capacitor during its operation. as a result of this model showed that the temperature, after a series of heat energy exchanges between the glass cover and all the internal parts of the distillate, with the absorbent part at the base of the distillate, exhibited the same behavior, which is increasing in its temperature steadily during the first hours of the day from (32.5-41.7 ) at (08:30 am) in the morning down to its top value (61.4-76.7 ) at (02:30 pm) and decline after this hour in the same bullish pattern. this is due to the greater difference between the amount of energy lost and acquired by the absorbent portion during the same daylight hours, as the amount of energy gained increases and the amount of lost energy decreases, leading to the highest energy gain and the least energy lost by the absorbent part at (02:30 pm), except the outer part of the additional condenser, which followed a similar behavior of air temperature, with its temperature gradually increasing slightly during the first hours of the day from (27 ) at (08:30 am) until it reached its peak (36.2 ) at (01:30 pm), then it decreases after this time slightly. this slight rise and slight decrease are due to the constant state of thermal balance between the two ends of the additional condenser by the heat exchange process between the outer part of the additional condenser and the cooling water.
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带附加冷凝器的太阳能蒸馏器传热模拟研究
太阳是到达地球表面的主要能量来源,它以电磁辐射的形式被称为太阳辐射,当它到达太阳蒸馏的玻璃罩的外表面时,作为热量的能量传递过程开始了。太阳能蒸馏物各部分之间的能量传递过程极大地控制了太阳能蒸馏物的性能,因此获得的能量越多,损失的能量越少,太阳能蒸馏物的生产率和效率就越高。本文建立了一个数学模型,计算了带有附加电容器的单斜太阳能蒸馏器在运行过程中各部分的热能量。这个模型的结果显示,温度,经过一系列的热能玻璃罩和所有内部交流的部分精华,吸收剂的底部的精华部分,表现出相同的行为,这是在增加其温度稳定在第一个小时的一天(32.5 - -41.7)凌晨(塔利班)点)到其最高价值(61.4 - -76.7)(pm) 02:30和衰退这一小时后在相同的看涨的模式。这是由于在相同的白天时间内,吸收部分损失和获得的能量之间的差异更大,因为获得的能量增加而损失的能量减少,导致吸收部分在(下午02:30)获得的能量最高,损失的能量最少,除了附加冷凝器的外部部分,它遵循类似的空气温度行为。从早上08:30(27)到下午01:30(36.2),气温在一天的头几个小时内逐渐上升,然后在这段时间后温度略有下降。这种轻微的上升和轻微的下降是由于附加冷凝器的外部部分与冷却水之间的热交换过程在附加冷凝器的两端之间保持恒定的热平衡状态。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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