Journal of Structural Engineering, its Applications and Analysis (e-ISSN:2582-4384)

In the face of global health challenges, the need for rapidly deployable and efficient quarantine facilities has become increasingly apparent. This paper presents a comprehensive analysis and design framework for a Pre-Engineered Quarantine Centre (PEQC) building. The proposed structure aims to provide a flexible and scalable solution that can be swiftly deployed in response to infectious disease outbreaks.

The analysis phase begins with a thorough examination of the unique requirements and constraints associated with quarantine facilities, considering factors such as infection control, ventilation systems, spatial arrangements, and adaptability to different site conditions. A risk assessment is conducted to identify potential hazards and vulnerabilities, informing the design process to prioritize safety and security.

The design phase integrates the principles of pre-engineering to develop a modular and prefabricated structure that optimizes construction time and cost while maintaining the necessary functionality for a quarantine facility. The building design incorporates state-of-the-art materials and technologies to ensure durability, energy efficiency, and compliance with relevant health and safety standards.

Key features of the proposed PEQC design include modular isolation units, dedicated zones for medical staff, efficient waste management systems, and advanced air filtration to prevent the spread of infectious agents. The layout prioritizes patient flow, minimizing cross-contamination risks and ensuring ease of medical surveillance.

Furthermore, the paper explores the integration of digital technologies for monitoring and managing the facility, including real-time data analytics, automated contact tracing, and telemedicine capabilities. These technological advancements enhance the overall efficiency and responsiveness of the quarantine center.

The proposed analysis and design framework provide a robust foundation for the development of Pre-Engineered Quarantine Centres, offering a versatile and adaptable solution to public health emergencies. The research contributes to the ongoing discourse on pandemic preparedness, emphasizing the importance of innovative and scalable infrastructure to safeguard public health on a global scale.

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