key: cord-0895718-a65wa9od authors: Zhou, Yu; Zhang, Zhonghua; Wang, Bo; Ren, Guangying; Qi, He; Wang, Xi title: Construction Time, Cost and Testing Data of a Prefabricated Isolation Medical Unit for COVID-19 date: 2020-07-24 journal: Data Brief DOI: 10.1016/j.dib.2020.106068 sha: d89f3c682ab33c4f60452ba8cd9a09d9de3e2bb7 doc_id: 895718 cord_uid: a65wa9od Coronavirus Disease 2019 (COVID-19) has been identified as a global pandemic by the World Health Organization (WHO). The breakout of COVID-19 in various countries and regions brings a great threat to people's life and adds an unprecedented high pressure on healthcare systems. Due to the high infectivity of COVID-19, high standard negative pressure isolation units are required to accommodate the patients with COVID-19 and protect health workers. A novel prefabricated negative pressure isolation medical unit was designed and constructed in Shenzhen, China to help to accommodate the patients with COVID-19. This article provides detailed construction cost, time and testing data for this isolation medical unit. Considering the construction happened during the lockdown in Shenzhen (and in China), the construction cost and time can provide precious and rare information as well as guidelines to construct or expand appropriate medical facilities to accommodate the patients with COVID-19. Civil and Structural Engineering Specific subject area a novel prefabricated negative pressure isolation medical unit. Tables. MS Excel file. How data were acquired The data about construction cost and time were collected during the construction. Performance data were collected during a test operation of a HVAC system for the medical unit. Brand and model of the testing equipment are listed as follows: TSI Incorporated: AccuBalance Air Capture Hood 8375. Raw. Analysed. During the construction, the cost data were collected and categorized as various major components, including the containers, windows & doors, sanitation, indoor equipment, heating, ventilation and air conditioning. During the test operation of a HVAC system, the performance data, including the pressure difference between rooms, pressure difference against atmosphere pressure and ventilation rate for the clean (fresh) air fans, were collected. Construction cost data of the prefabricated isolation medical unit for the COVID-19, available in an associated Excel spreadsheet, and the construction time, testing and evaluation data of the prefabricated isolation medical unit for the COVID-19, available in tables within the main text.  These data provide precious and rare information and guidelines to expand high standard medical facilities to accommodate the patients with COVID-2019.  Medical and engineering professionals currently combat COVID-19 or consider expanding medical facilities due to COVID-19.  The detailed construction time and cost breakdown of a negative pressure medical unit are presented, which will enable a cost analysis and comparison with the other medical applications and construction methods. The data presented in this article have been collected under the construction of a high cleanness negative pressure prefabricated isolation medical unit constructed for the patients with COVID-19, locating at Pingshan People's Hospital, Shenzhen, China. In this project, this medical unit was constructed within five working days via prefabricated modular construction. Table 1 shows the daily construction progress during this period. The information includes the number of workers engaged each day, the working hours as well as the progress. As the construction happened via the lockdown in Shenzhen (and China), the cost of installation can be unique. Shown in the attached spreadsheet, the collected installation cost data were categorized as various major components, including the containers, windows & doors, sanitation, indoor equipment, heating, ventilation and air conditioning. All the costs listed are in CNY (Chinese Yuan). The last but not the least, testing and evaluation regarding the pressure and air flow rates in each room have been conducted. Table 2 shows the details of the measured pressure difference between rooms, and the room with higher pressure is shown first (As an example, Ward 1 has a higher pressure than Restroom 1). Table 3 then presents the measured pressure difference between each room and the atmosphere pressure (Note: the negative value means that the pressure in the room is lower than atmosphere pressure). Lastly, Table 4 shows the results of the measured ventilation rates for the clean (fresh) air fans in each room. The locations of the fans are shown in Figure 1 . The experimental design and methods will then be discussed in the next section. An appropriate indoor environment can be essential to the isolation wards to form effective protections for the patients and medical workers [1] [2] [3] . The parameters need to be considered including indoor air temperature, relative humidity [4] , ventilation and differential pressure control [5] . While indoor air temperature and relative humidity can be easily satisfied with the air conditioning system, the ventilation and differential pressure control can be critical and challengeable for isolation medical units [6] . In this practice, according to the cleanliness and functions, the medical unit is divided into five zones, such as the patient corridor, the patient room, the patient restroom, the buffer room and the medical corridor, and each with an independent fresh air conditioning system. Gradient pressure air distribution is adopted to achieve this aim, where different levels of negative pressure are distributed in different zones ( Figure 2 ). In this project, the isolation wards where patients are located are designed to have the -10 Pa comparing with the atmosphere and the restroom is kept as -15 Pa. This is to ensure that the clean air continues flowing into the patient rooms and the exhausted air can be pulled out without leaking to the health care workers' working area. To achieve the design mentioned above, it took five continuous days during the construction period. The daily construction progress is organised and presented in this article ( Table 1 ). The associated installation cost is also reported to reflect the price under the unprecedented challenges (due to lockdown) in the supply chain of equipment as well as the labour and workers (shown in the attached spreadsheet). The evaluation and testing were then conducted before handing over to the hospital. The testing includes the pressure differences and air flow rates in each room. The locations of the fans tested are shown in Figure 1 . The top view of the medical unit constructed is shown in Figure 3 . Effects of Indoor Environmental Parameters related to Building HVAC Systems on Patients Does The Architecture Of Hospital Facilities Influence Nosocomial Infection Rates? Investigating a safe ventilation rate for the prevention of indoor SARS transmission: An attempt based on a simulation approach Literature Review of the Effect of Temperature and Humidity on Viruses Control and management of hospital indoor air quality The ventilation of multiple-bed hospital wards: review and analysis Assistance from Tsinghua University and Pingshan People's Hospital is highly appreciated. The authors declare that they have no known competing financial interests or personal relationships which have, or could be perceived to have, influenced the work reported in this article.