References
- Wang, Y., & Cao, Z. (2017). Industrial Building Environment: Old Problem and New Challenge. Indoor Built Environ, 26: 1035–1039.
- Xu, C., & Liu, L. (2018). Personalized Ventilation: One Possible Solution for Airborne Infection Control in Highly Occupied Space? Indoor Built Environ, 27, 873–876.
- Janushevskis, A., Vejanand S. R., & Gulevskis, A. (2022). Analysis of Different Shape Ventilation Elements for Protective Clothing. WSEAS Transactions on Fluid Mechanics, 17, 140–146.
- Barry, J., Hill, R., Brasser, P., Sobera, M., Kleijn, C.R., & Gibson, P. W. (2003). Computational Fluid Dynamics Modeling of Fabric Systems for Intelligent Garment Design. MRS Bulletin, 28 (08).
- Udayraj, B. C. (2022). A Coupled CFDThermoregulation Model for Air Ventilation Clothing. Journal of Energy and Buildings, 268, 112206.
- Epstein, Y., Shapiro, Y., & Brill, S. (2010). Comparison between Different Auxiliary Cooling Devices in a Severe Hot/Dry Climate. Ergonomics, 29 (1), 41–48.
- Pasut, W., Zhang, H., Arens, E., & Zhai, Y. (2015). Energy-efficient Comfort with a Heated/Cooled Chair: Results from Human Subject Tests. Building and Environment, 84, 10–21.
- Lopez, G., Tokuda, T., Isoyama, N., Hosaka, H., & Itao, K. (2016). Development of a Wrist-Band Type Device for Low-Energy Consumption and Personalized Thermal Comfort. MECATRONICS 2016/17th Int. Conf. Res. Educ. Mechatronics, 209–212.
- He, Y., Li, N., He, M., & He, D. (2017). Using Radiant Cooling Desk for Maintaining Comfort in Hot Environment. Energy and Buildings, 145, 144–154.
- Huang, L., Ouyang, Q., Zhu, Y., & Jiang, L. (2013). A Study about the Demand for Air Movement in Warm Environment. Building and Environment, 61, 27–33.
- Udayraj, Wang, F., Song, W., Ke, Y., Xu, P., Chow, C. W. S., & Noor, N. (2019). Performance Enhancement of Hybrid Personal Cooling Clothing in a Hot Environment: PCM Cooling Energy Management with Additional Insulation. Ergonomics, 62 (7), 928–939.
- Mneimneh, F., Ghaddar, N., Ghali, K., & Itani, M. (2021). The Effectiveness of Evaporative Cooling Vest with Ventilation Fans on the Thermal State of Persons with Paraplegia during Exercise. Building and Environment, 206, 108356.
- Xu, P., Kang, Z., Wang, F., & Udayraj. (2020). A Numerical Analysis of the Cooling Performance of a Hybrid Personal Cooling System (HPCS): Effects of Ambient Temperature and Relative Humidity. International Journal of Environmental Research and Public Health, 17 (14), 4995.
- Wang, F., Ke, Y., Udayraj, Yang, B., Xu, P., & Noor, N. (2020). Effect of Cooling Strategies on Overall Performance of a Hybrid Personal Cooling System Incorporated with Phase Change Materials (PCMs) and Electric Fans. Journal of Thermal Biology, 92, 102655.
- Watkins, S.M. (1995). Clothing: The Portable Environment (2nd ed.). Iowa State University Press.
- Lim, J., Choi, H., Roh, E. K., Yoo, H., & Kim, E. (2015). Assessment of Airflow and Microclimate for the Running Wear Jacket with Slits Using CFD Simulation. Fashion and Textiles, 2, 1.
- Janushevskis, A., Vejanand, S. R., & Gulevskis, A. (2023). Shape Optimization of Ventilation Elements for Protective Clothing by Using Metamodeling Approach. 22th International Scientific Conference Engineering for Rural Development, 23, 164–172.
- Kumar, R., Aggarwal, R.K., Sharma, J.D., & Pathania, S. (2012). Predicting Energy Requirement for Cooling the Building Using Artificial Network. Journal of Technology Innovations in Renewable Energy, 1 (2), 113–121.
- Janushevskis, A., Vejanand, S. R., & Gulevskis, A. (2022). Comparative Analysis of Different Shape Ventilation Elements for Protective Clothing. Engineering for Rural Development, Jelgava, 25–27 May 2022.
- Giering, K., Lamprecht, I., & Minet, O. (1996). Specific Heat Capacities of Human and Animal Tissues. Proceedings of SPIE – The International Society for Optical Engineering, 2624, 188–197.