Open Access Journal

ISSN : 2456-1290 (Online)

International Journal of Engineering Research in Computer Science and Engineering (IJERCSE)

Monthly Journal for Computer Science and Engineering

Open Access Journal

International Journal of Engineering Research in Mechanical and Civil Engineering (IJERMCE)

Monthly Journal for Mechanical and Civil Engineering

ISSN : 2456-1290 (Online)

Comparative Analysis of Different Three Types of Room Heater for Thermal Effect

Author : Vinit Kumar 1 Rajnish Singh 2 Shashank Kumar 3

Date of Publication :18th May 2022

Abstract: The present work experimentally carried the study of comparative analysis of different type of room heater for space heating and thermal comfort. In cold climate the human being is required thermal comfort. In rural areas, humans are using the domestic heater, blower and other different types of heater for thermal comfort. Although sometimes used of these types of heater results oxygen level is down and so it is harmful to health. A comparative analysis was done in this work to reduce these problems. In these experiments, three different types of heater were used, and in the present work suggested the best type of heater for room heating in cold climate. A room is heated with a volume of 3 x 2.4 x 3.65 m3 for thermal comfort, the temperature and humidity is measured and calculates the total temperature rise and humidity drop of the room. The comfort and combine study of performance of blower, rod heater and circular heater was done in the Ramanujan hostel room at Kamla Nehru Institute of Technology, Sultanpur during night. The study was confined to 9 PM to 4 AM from January 2019 to March 2019. The experimental study was done in night so solar radiation by sun is negligible and the reading is effectively observed. Therefore, the three cases were carried experimentally for room heating in cold climate and a comparative analysis is done of these three cases (blower, circular heater and rod heater).

Reference :

    1. C. Hemmer, G. Polidori, C. Popa, Temperature optimization of an electric heater by emissivity variation of heating elements, Case Stud. Therm. Eng. 4 (2014) 187–192
    2. H. Ambarita, A. H. Nasution, N. M. Siahaan, H. Kawai, Performance of a clothes drying cabinet by utilizing waste heat from a split-type residential air conditioner, Case Stud. Therm. Eng. 8 (2016) 105–114.
    3. T. H. Pedersen, R. E. Hedegaard, K. F. Kristensen, B. Gadgaard, S. Petersen, The effect of including hydronic radiator dynamics in model predictive control of space heating, Energy & Buildings 183 (2019) 772–784.
    4. T. Ariztia, F. Fonseca, O. Bernasconi, Heating ecologies: Resituating stocking and maintenance in domestic heating, Energy Research & Social Science 47 (2019) 128–136.
    5.  C. Su, H. Madani, B. Palm, Heating solutions for residential buildings in China: Current status and future outlook, Energy Conversion and Management 177 (2018) 493–510
    6.  M. Khaled, M. Ramadan, Heating fresh air by hot exhaust air of HVAC system, Case Stud. Therm. Eng. 8 (2016) 398– 402.
    7. M. Ramadan, M. Gad El Rab, and M. Khaled, Parametric analysis of air-water heat recovery concept applied to HVAC systems: effect of mass flow rates, Case Stud. Therm. Eng. 6 (2015) 61–68.
    8. W. Li, C. Koo, S. Hyun Cha, T. Hong, J. Oh, A novel real-time method for HVAC system operation to improve indoor environmental quality in meeting rooms, Building and Environment 144 (2018) 365–385.
    9. M. Kharseh, L. Altorkmany, M. Al-Khawaj, F. Hassani, Warming impact on energy use of HVAC system in buildings of different thermal qualities and in different climates, Energy Conversion and Management 81 (2014) 106–111.
    10. Nordell B. Thermal pollution causes global warming. Glob Planet Change 2003;38:305–12.
    11. Nordell B, Gervet B. Global energy accumulation and net heat emission. Int J Glob Warm 2009; 1:373–91. 378.
    12. D. Heinzerling, S. Schiavon, T. Webster, E. Arens, Indoor environmental quality assessment models: a literature review and a proposed weighting and classification scheme, Build. Environ. 70 (2013) 210–222
    13. I. Sarbu, C. Sebarchievici, Aspects of indoor environmental quality assessment in buildings, Energy Build. 60 (2013) 410– 419.
    14. S.P. Corgnati, R. Ansaldi, M. Filippi, Thermal comfort in Italian classrooms under free running conditions during mid-seasons: assessment through objective and subjective approaches, Build. Environ. 44 (4) (2009) 785–792.
    15. Z. Pei, B. Lin, Y. Liu, Y. Zhu, Comparative study on the indoor environment quality of green office buildings in China with a long-term field measurement and investigation, Build. Environ. 84 (2015) 80–88

Recent Article