International Journal of

---

Using the concept of passive cooling systems has been utilized as a solution to improve thermal and wind comfort and to decrease energy consumption and environmental pollution, recently. Modern windcatcher, as its name denotes, is an architectural element which is using the concept of Badgir and combined proper devices to create ventilation in buildings using wind energy, but including modern technology. It means that the modern windcatcher is an improved model of traditional windcatchers and the design of modern windcatchers is based on computations and they have been analyzed and improved, unlike the ancient ones. The current investigation focused on the technology of modern windcatchers to face how modern technology uses various methods to foster the windcatchers' performance. The purpose of this manuscript is to summarize previous studies on the technology of modern wind catchers and gives insight into the application of windcatchers as passive cooling systems. different employed methods to foster the windcatchers' performance.

---

High temperatures and air pollution are significant challenges in ensuring fresh air supply in the hot-humid climate of Asalouye City. These conditions compel residents to rely heavily on mechanical cooling, which subsequently escalates energy consumption and deteriorates indoor air quality. The primary air pollutants include Particulate Matter (PM), Volatile Organic Compounds (VOCs), and microorganisms. Fiber filters and electrostatic filters are the most common methods for purifying PMs from the air, with the electrostatic method offering advantages such as high efficiency, the ability to remove a wide range of particles, low-pressure drop, and no need for frequent replacement. This study proposed a ventilation system integrating a window,
a precipitator using electrostatic technology, a cooling coil, and an exhaust fan. The system's performance was evaluated using CFD simulation in Ansys-Fluent software (2021) to assess its effectiveness in reducing PM concentrations, pre-cooling incoming air, and maintaining the standard ventilation rate. The findings revealed that at air velocities of 6 m/s and 1 m/s, the system could completely remove copper, nickel, and sulfur particles with diameters of 0.1 µ and 10 µ. Additionally, the distance between the system's air inlet (window opening) and its air outlet (where air enters the interior) significantly influences the particle reduction level. The proposed cooling coil, however, only managed to reduce the air temperature by 2°C. In the absence of wind, an exhaust fan with a pressure jump of at least 250 Pa or 500 Pa is necessary to achieve the standard airflow and ventilation rate.