Noise Levels and Comfort Levels of Populations Living Around Mistar Cokrokusumo Bangkal District

Bilah Samping Artikel

PDF (English)
Terbitan
Vol 20 No 1 (2023): Jurnal Kesehatan Lingkungan Volume 20 No. 1, Januari 2023
Diterbitkan: Jan 1, 2023

Isi Artikel Utama

Rully Sapwandi
Poltekkes Kemenkes Banjarmasin Jurusan Kesehatan Lingkungan
Junaidi Junaidi
Poltekkes Kemenkes Banjarmasin Jurusan Kesehatan Lingkungan
Zulfikar Ali As
Poltekkes Kemenkes Banjarmasin Jurusan Kesehatan Lingkungan
Muhammad Pahruddin
Poltekkes Kemenkes Banjarmasin Jurusan Kesehatan Lingkungan

Abstrak

Today, many houses are located on the edge of highways, potentially exposing these homes to additional noise from the traffic flow. This study aims to determine the relationship between noise levels and the comfort levels of residential homes in the Bangkal sub-district. This observational study, which has a cross-sectional design, includes 12 sample points for noise measurement and 77 houses directly adjacent to the road for comfort level sampling. Noise levels were measured using a sound level meter, while traffic density was measured using a compass and counter. The relationship between the two variables was analyzed using the Spearman correlation test. Results showed that the volume of traffic flow ranged from 334 pcu/hour to 402 pcu/hour. The highest noise level was recorded at TS-7 (65.7 dBA) and the lowest at TS-9 (61.7 dBA). According to the South Kalimantan governor's regulation number 53 of 2007, all 12 sample points of noise measurement exceed the quality standard. The average correlation between noise level and comfort level indicated that 88% of households reported being less comfortable, 12% felt uncomfortable, and none felt comfortable. Houses can reduce road traffic noise by installing thick curtains on their windows and doors, planting trees and ornamental plants in pots, and constructing artificial walls.

Rincian Artikel

Bagian
policies
Creative Commons License

Artikel ini berlisensiCreative Commons Attribution-ShareAlike 4.0 International License.

(CC BY-SA): Lisensi ini mengizinkan untuk Berbagi — menyalin dan mendistribusikan ulang materi dalam media atau format apa pun, Mengadaptasi — mencampur ulang, mengubah, dan membangun dari materi tersebut, untuk tujuan apa pun, bahkan secara komersial.

Hak cipta atas artikel yang diterima akan dialihkan kepada jurnal sebagai penerbit jurnal tersebut. Hak cipta yang dimaksud mencakup hak untuk menerbitkan artikel dalam berbagai bentuk (termasuk cetak ulang). Jurnal mempertahankan hak penerbitan atas artikel-artikel yang telah diterbitkan.

Penulis diizinkan untuk menyebarluaskan artikel yang telah diterbitkan dengan membagikan tautan/DOI artikel di jurnal. Penulis diizinkan menggunakan artikel mereka untuk tujuan hukum apa pun yang dianggap perlu tanpa izin tertulis dari jurnal, dengan syarat mencantumkan pengakuan atas publikasi awal di jurnal ini.

Referensi

Menteri Negara Lingkungan Hidup. Keputusan Menteri Lingkungan Hidup No. 48 Tahun 1996 Tentang Baku Mutu Kebisingan. 1996.

World Health Organization. World Health Organization Guideline On Community Noise. Fact Sheet No. 258 Revised February 2001.

Workplace Health And Safety (WHS) Code Of Practice For Noise Management At Work. Australia. 1993.

Putri, N. (2018). Relationship Between Road Noise Levels and Students' Concentration Levels at Madrasah Aliyah Swasta Mas Nur Ibrahimy Rantauprapat. Kesehat. Masy., 1–128.

Kolcaba, K. (2003). Comfort theory and practice: A vision for holistic health care and research. New York: Springer Publishing Company.

Saputra, A. (2021). Noise Levels, Wind Direction, and Traffic Density Around Jalan H. M. Cokrokusumo Residential Area, Cempaka Village.

Shaleha, M. (2020). Relationship Between Lighting, Temperature, and Humidity with Occupant Comfort in Wetland Settlements in Hulu Sungai Utara Regency.

Jin, Y., Jiang, H., & Kang, J. (2020). Effects of sound types and sound levels on subjective environmental evaluations in different seasons. Building and Environment, 183, 107215. https://doi.org/10.1016/j.buildenv.2020.107215

Pachiappan, Y., & Govindaraj, B. (2013). Regression modelling of traffic noise pollution. Journal of the Croatian Association of Civil Engineers, 65(12), 1089-1096. https://doi.org/10.14256/jce.949.2013

Dzakiyyah, A., & Gaputra, A. (2022). Audial comfort evaluation of the urban park libraries, case study: Bima Microlibrary in Bandung, Indonesia. Iop Conference Series Earth and Environmental Science, 1058(1), 012012. https://doi.org/10.1088/1755-1315/1058/1/012012

Gumelar, R., Ramadhan, T., & Maknun, J. (2022). Evaluation of the audial comfort of the mosque on the cross-city route: Al-Ghani Mosque Ciamis. Iop Conference Series Earth and Environmental Science, 1058(1), 012003. https://doi.org/10.1088/1755-1315/1058/1/012003

Webster, R., & Thompson, D. (1986). Sleep in hospital. Journal of Advanced Nursing, 11(4), 447-457. https://doi.org/10.1111/j.1365-2648.1986.tb01272.x

Ivov, E., Marocco, E., & Lennox, J. (2011). A real-time transport protocol (rtp) header extension for client-to-mixer audio level indication. https://doi.org/10.17487/rfc6464

Ivov, E., Marocco, E., & Lennox, J. (2011). A real-time transport protocol (rtp) header extension for mixer-to-client audio level indication. https://doi.org/10.17487/rfc6465

Pachiappan, Y., & Govindaraj, B. (2013). Regression modelling of traffic noise pollution. Journal of the Croatian Association of Civil Engineers, 65(12), 1089-1096. https://doi.org/10.14256/jce.949.2013

Marques, G., & Pitarma, R. (2020). A real-time noise monitoring system based on internet of things for enhanced acoustic comfort and occupational health. IEEE Access, 8, 139741-139755. https://doi.org/10.1109/access.2020.3012919

Aletta, F., Asdrubali, F., Blasiis, M., Evangelisti, L., & Guattari, C. (2022). Influence of soundscape in the experience of an urban area: A case study in Rome. https://doi.org/10.54941/ahfe1002347

Patania, F., Gagliano, A., Nocera, F., & Galesi, A. (2013). Analysis of acoustic climate on board public transport. https://doi.org/10.2495/ehr130011

Viscardi, M., & Arena, M. (2018). Development of a dynamic tool for aircraft noise reproduction. Matec Web of Conferences, 210, 05018. https://doi.org/10.1051/matecconf/201821005018

Amoatey, P., Al-Harthy, I., Ma, A., Al-Jabri, K., & Al-Mamun, A. (2021). Spatiotemporal assessment of the effect of indoor noise on annoyance, health and comfort in hospital wards and intensive care unit. https://doi.org/10.21203/rs.3.rs-602718/v1

Andargie, M. (2023). Assessment of indoor exposure to outdoor environmental noise and effects on occupant comfort in multi-unit residential buildings. Building Acoustics, 30(3), 293-313. https://doi.org/10.1177/1351010x231194471

Casaccia, S., Jokinen, K., Naccarelli, R., & Revel, G. (2022). Well-being and comfort of ageing people based on indoor environmental conditions: Preliminary study on human-coach conversation. https://doi.org/10.1109/metrolivenv54405.2022.9826905

Anggiandari, N. (2022). Implementation of soundscape at rail boundaries, case study JL. Haur Jaya, Bogor City. Journal of Architectural Research and Education, 4(2), 175-184. https://doi.org/10.17509/jare.v4i2.55737

Lorenzino, M., D’Agostin, F., Rigutti, S., Bovenzi, M., Fantoni, C., & Bregant, L. (2020). Acoustic comfort depends on the psychological state of the individual. Ergonomics, 63(12), 1485-1501. https://doi.org/10.1080/00140139.2020.1808249

Jones, P., & Comfort, D. (2019). A commentary on the localisation of the sustainable development goals. Journal of Public Affairs, 20(1). https://doi.org/10.1002/pa.1943.