气泡曝气器产生的露点温度建模与模拟

Q3 Engineering

Acta IMEKO Pub Date : 2023-12-24 DOI:10.21014/actaimeko.v12i4.1568

Arfan Sindhu Tistomo, Aditya Achmadi, Melati Azizka Fajria, S. Viridi, Muhammad Miftahul Munir, S. Suprijadi

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引用次数: 0

摘要

露点温度可以通过几种方法使空气中的水蒸气达到饱和而产生，其中一种方法是在一个被称为饱和器的封闭空间中产生通过水的小气泡。在实际应用中，可以使用露点仪测量该系统产生的露点温度。然而，通过理论方法预测产生的露点温度之前还没有人提出过。因此，本研究通过模拟来确定露点温度。然后将结果与实验数据进行比较。实验遵循单压湿度发生器原理，将包含气泡曝气器的饱和器浸入搅拌液浴中。浴槽温度设定为 25 °C，气体流速从 0.1 升/分钟调整到 0.4 升/分钟。露点温度使用 373 LHX 冷镜露点仪测量。另一方面，模拟采用蒙特卡罗方法，物理模型包括对流和气泡能量变化之间的热平衡。对流传热系数由气泡动力学行为决定，与气泡大小和气泡速度有关。模拟得到的露点温度假定与气泡温度相同。因此，模拟数据与实验数据非常吻合。

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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Modeling and simulation of dew point temperature generated by a bubble aerator

The dew point temperature can be generated by saturating air with water vapor through several methods, one of which is by creating small-sized air bubbles passed through water in an enclosed space known as a saturator. In practical terms, the dew point temperature produced by this system can be determined by measuring it using a dew point meter. However, the prediction of the dew point temperature generated through theoretical approaches has not been presented before. Thus, in this study, a simulation has been conducted to determine the dew point temperature. The result is then compared to the experimental data. The experiment follows the single pressure humidity generator principle, where a saturator containing a bubble aerator is immersed in a stirred liquid bath. The bath temperature is set to 25 °C, and the gas flow rate is adjusted from 0.1 lpm to 0.4 lpm. The dew point temperature is measured using a 373 LHX chilled mirror dew point meter. On the other hand, the simulation is performed using the Monte Carlo method, and the physical model involves a heat balance between convection and the change in bubble energy. The convection heat transfer coefficient is determined by the behavior of bubble dynamics, which is related to the bubble size and bubble velocity. The dew point temperature obtained from the simulation is assumed to be the same as the bubble temperature. As a result, the simulation data align well with the experimental data.

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来源期刊

Acta IMEKO Engineering-Mechanical Engineering

CiteScore

2.50

自引率

0.00%

发文量

期刊介绍： The main goal of this journal is the enhancement of academic activities of IMEKO and a wider dissemination of scientific output from IMEKO TC events. High-quality papers presented at IMEKO conferences, workshops or congresses are seleted by the event organizers and the authors are invited to publish an enhanced version of their paper in this journal. The journal also publishes scientific articles on measurement and instrumentation not related to an IMEKO event.