Investigating the effects of geometry and material on acoustic characteristics of hospital rooms
Subject Areas : Journal of Simulation and Analysis of Novel Technologies in Mechanical EngineeringMehdi Salehi 1 , Rozita Salehi 2
1 - Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, Iran
2 - Department of Architecture Faculty of Art, Architecture and Urban Planning, Najafabad Branch, Islamic Azad University, Najafabad, Iran
Keywords: Medical space architecture, Acoustics, Noise reduction, Closed space, Building materials,
Abstract :
The purpose of this study is to find solutions to improve the acoustic characteristics of therapeutic spaces in the design and construction phases. In many architectural designs, the importance of acoustics is not considered, although the acoustic performance of buildings is of importance in many cases. Hospitals are one of such cases. This study is focused on the effect of the geometry and material of the internal walls of the patient's hospital room on its acoustic performance through computer acoustic simulations. Acoustic simulations have been implemented in Odeon software. The acoustic calculations in this software are geometric and the most important acoustic parameters of the patient's room have been investigated. Reverberation time is one of the key parameters. A set of dimensions and common materials for a hospital room were considered as input for acoustic simulation. The results of this research specifically suggest the optimal dimensions and materials of a three-bed patient room. Based on the simulations, a three-bed room with dimensions 5.3 x 1.7 square meters and vinyl wall material leads to the optimal amount reverberation time. Although the use of porous acoustic material in the walls can significantly improve the acoustic characteristics of the room, but due to the health considerations of infectious environments, the use of such materials is not allowed. In some cases, conflicts arise between the methods of improving these multiple parameters. In this study, the reverberation time has the highest priority over other parameters. 5/3 × 1/7 متر مربع و جنس دیواره¬ وینیل منجر به مقدار بهینه زمان واخنش می¬شود. البته استفاده از متریال های اکوستیک، که عموما متخلخل می باشند، می تواند شرایط را بیش از این ارتقا دهد اما استفاده از چنین ساختارهایی به دلیل ملاحظات عفونی در مراکز درمانی مجاز نمی باشد. در برخی موارد تعارض میان روش های بهبود این پارامترهای چندگانه ایجاد می گردد. در این مطالعه، پارامتر زمان واخنش بالاترین اولویت را نسبت به سایر پارامترها دارد.
[1] Rangga, F. et al. (2024). Hospital interior design with healing environment approach. in AIP Conference Proceedings. AIP Publishing.
[2] Raghuwanshi, N.K. et al. (2024). Noise effects, analysis and control in hospitals-A review. Noise & Vibration Worldwide, 09574565241235326.
[3] Bliefnick, J.M., Ryherd, E.E. and Jackson R. (2019). Evaluating hospital soundscapes to improve patient experience. The Journal of the Acoustical Society of America. 145(2). 1117.
[4] Jerlehag, C. et al. (2018). Acoustic environments of patient room in a typical geriatric ward. Applied Acoustics. 133. 186-193.
[5] Montes-González, D. et al. (2019). Environmental Noise around Hospital Areas: A Case Study. Environments. 6(4). 41.
[6] Adams, C. et al. (2024). As loud as a construction site: Noise levels in the emergency department. Australasian Emergency Care. 27(1). 26-29.
[7] Wang, T.C. et al. (2024). Impact of occupational noise exposure on the hearing level in hospital staffs: a longitudinal study. Environmental Science and Pollution Research. 1-10.
[8] Chen, C. Y. (2015). Characterizing Subjective Noisiness in Hospital Lobbies. Archives of Acoustics. 40(2). 235-246.
[9] Hill, J.N. and LaVela, S.L. (2015). Noise Levels in Patient Rooms and at Nursing Stations at Three VA Medical Centers. Herd. 9(1). 54-63.
[10] Xie, H., Kang, J. and Mills G.H. (2009). Clinical review: The impact of noise on patients' sleep and the effectiveness of noise reduction strategies in intensive care units. Critical Care. 13(2). 208.
[11] Mommersteeg, B. (2024). Approximations: On some ways to listen to a building “in the making”. Science, Technology, & Human Values. 49(2. 238-262.
[12] Herman, M. and Saragih, J.B. (2024). Spatial Acoustic Approach: Sustainable Design Methods in Creative Centre Building. in IOP Conference Series: Earth and Environmental Science. IOP Publishing.
[13] Coffeen, R.C. (2012). Techniques for teaching building acoustics and noise control to university architecture students. The Journal of the Acoustical Society of America. 132(3). 1922-1922.
[14] Lokki, T. and Pätynen, J. (2019). Architectural Features That Make Music Bloom in Concert Halls. Acoustics. 1(2). 439-449.
[15] Peters, B. (2015). Integrating acoustic simulation in architectural design workflows: the FabPod meeting room prototype. SIMULATION. 91(9). 787-808.
[16] Shield, B.M. and Dockrell, J.E. (2003). The Effects of Noise on Children at School: A Review. Building Acoustics. 10(2). 97-116.
[17] Cavanaugh, W.J. (2009). Architectural Acoustics: Principles and Practice, 2nd Edition. John Wiley & Sons.
[18] Ellingson, R.M., Gallun, F.J. and Bock, G. (2015). Measurement with verification of stationary signals and noise in extremely quiet environments: Measuring below the noise floor. The Journal of the Acoustical Society of America. 137(3). 1164-1179.
[19] jedidi, M. (2016). Acoustic Study of an Auditorium by the Determination of Reverberation Time and Speech Transmission Index. IUST. 26(1). 25-32.
[20] Soha Eldakdoky, A.E. (2017). Acoustic improvement on two lecture auditoria: Simulation and experiment. Frontiers of Architectural Research. 6(1). 1-16.
[21] Howard, C.Q. and Cazzolato, B.S. (2017). Acoustic analyses using Matlab and Ansys. Boca Raton: CRC Press.
[22] Ermann, M. (2015). Architectural acoustics illustrated. The Journal of the Acoustical Society of America. 137(4). 2358-2358.
[23] Nyembwe, J.P.K.B. et al. (2023). Evaluation of Noise Level in Intensive Care Units of Hospitals and Noise Mitigation Strategies, Case Study: Democratic Republic of Congo. Buildings. 13(2). 278.
[24] Swanson, D.C. (2010). Architectural Acoustics: Principles and Practice, 2nd ed. John Wiley & Sons Press.