Contamination in Heat Exchangers: Types, Energy Effects and Prevention Methods

Mehmet Akif Kartal

doi:10.61927/igmin209

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Nerea Gamonal and Concepción Ornosa

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Exploring Markov Decision Processes: A Comprehensive Survey of Optimization Applications and Techniques

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Engineering Group Research Article 記事ID: igmin209

Contamination in Heat Exchangers: Types, Energy Effects and Prevention Methods

Mechanical Engineering Energy Engineering

Mehmet Akif Kartal ^*

Affiliation

Bandırma Onyedi Eylül University, Distance Education Application and Research Center, 10200 Bandırma, Balıkesir, Turkey

DOI10.61927/igmin209 全文HTML 全文PDF この記事を引用する

要約

Exchangers are thoroughly used equipment for heat transfer. These equipment play a climacteric role in variegated business administration and buildings by providing heat exchange between two fluids. However, over time, exchangers can be subject to variegated problems such as contamination and sediment build-up. This can diminish heat transfer efficiency, leading to energy waste and equipment malfunctions. Calcification is a problem that comes off when water becomes saturated with hard minerals and exceeds the solubility of these minerals. These minerals precipitate as a consequence of water evaporation or chemical reactions and form a solid layer called limestone. Limescale can bring variegated problems in homes, business administration, and water transportation systems. Lime accumulates on heat transfer superficies, reducing the superficies area of these superficies. This reduces the superficies area available for heat transfer and inhibits heat transfer. The thermal conductivity of lime is lower than water. Scale, which is the formation of a scale layer on heat transfer superficies, reduces the thermal conductivity of these superficies and prevents heat transfer. This study focuses on the types of contamination in heat exchangers, the effect of contamination on heat transfer and other factors, and methods of clogging.

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参考文献

Pan M, Bulatov I, Smith R. Improving heat recovery in retrofitting heat exchanger networks with heat transfer intensification, pressure drop constraint, and fouling mitigation. Appl Energy. 2016; 161:611-626.
Guha A. Transport and deposition of particles in turbulent and laminar flow. Annu Rev Fluid Mech. 2008; 40: 311-341.
Zhao B, Wu J. Modeling particle deposition from fully developed turbulent flow in ventilation duct. Atmos Environ. 2006; 40:457-466.
Cui XZ, Liu QS, Zhang CY. Physical factors affecting the transport and deposition of particles in saturated porous media. Water Sci Tech-W Sup. 2017; 17(6):1616-1625.
Bayat M, Aminian J, Bazmi M, Shahhosseini S, Sharifi K. CFD modeling of fouling in crude oil pre-heaters. Energy Convers Manage. 2012; 64:344-350.
Jradi R, Marvillet C, Jeday MR. Estimation and sensitivity analysis of fouling resistance in phosphoric acid/steam heat exchanger using artificial neural networks and regression methods. Sci Rep. 2023 Oct 19; 13(1):17889. doi: 10.1038/s41598-023-44516-6. PMID: 37857645; PMCID: PMC10587106.
Kazi NS. Fouling and Fouling Mitigation on Heat Exchanger Surfaces. In: InTech; 2012. doi: 10.5772/32990.
Sundar S, Rajagopal MC, Zhao H, Kuntumalla G, Meng Y, Chang HC, Shao C, Ferreira P, Miljkovic N, Sinha S, Salapaka S. Fouling modeling and prediction approach for heat exchangers using deep learning. Int J Heat Mass Transfer. 2020; 159:120112.
Kostoglou M, Andritsos N, Karabelas AJ. Flow of supersaturated solutions in pipes. Modelling bulk precipitation and scale formation. Chem Eng Commun. 1995; 133:107-133.
Amjad Z. Calcium Sulfate Dihydrate (Gypsum) Scale Formation on Heat Exchanger Surface: The Influence of Scale Inhibitors. J Colloid Interface Sci. 1988; 132(2).
Sheikholeslami R. Nucleation and Kinetics of Mixed Salts in Scaling. AIChE J. 2003; 49(January):194-202.
Sheikholeslami R. Calcium Sulfate Fouling - Precipitation or Particulate; A Proposed Composite Model. Heat Transfer Eng. 2000; 21(2):24-33.
Taberok J, Ritter RB, Palen JW. Heat Transfer; Fouling: The Major Unresolved Problem in Heat Transfer. Chem Eng Prog. 1972; 68(2):59-67.
Kho T, Muller-Steinhagen H. An experimental and numerical investigation of heat transfer fouling and fluid flow in flat plate heat exchangers. Trans IChemE, Part A. 1999; 77:124-130.Bott TR.
Fouling of Heat Exchangers. ELSEVIER science BV. 1995.
Bailey K. Optimise Heat Exchanger Operations By Minimising Fouling. Hydrocarbon Process. 1999 Jul; 113-127.
Epstein N. Fouling in Heat Exchangers. In Proceedings of the 2nd International Conference Heat Transfer. 1978.
Muller-Steinhagen H, Zhao Q, Helali-Zadeh A, Ren XG. The effect surface properties of CaSO4 scale formation during convective heat transfer and subcooled flow boiling. Can J Chem Eng. 2000 Feb; 78:12-20.
Mukherjee, R., Conquer heat exchanger fouling. Hydrocarbon Processing. 1996; 121-127.

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[1] Pan M, Bulatov I, Smith R. Improving heat recovery in retrofitting heat exchanger networks with heat transfer intensification, pressure drop constraint, and fouling mitigation. Appl Energy. 2016; 161:611-626.

[2] Guha A. Transport and deposition of particles in turbulent and laminar flow. Annu Rev Fluid Mech. 2008; 40: 311-341.

[3] Zhao B, Wu J. Modeling particle deposition from fully developed turbulent flow in ventilation duct. Atmos Environ. 2006; 40:457-466.

[4] Cui XZ, Liu QS, Zhang CY. Physical factors affecting the transport and deposition of particles in saturated porous media. Water Sci Tech-W Sup. 2017; 17(6):1616-1625.

[5] Bayat M, Aminian J, Bazmi M, Shahhosseini S, Sharifi K. CFD modeling of fouling in crude oil pre-heaters. Energy Convers Manage. 2012; 64:344-350.

[6] Jradi R, Marvillet C, Jeday MR. Estimation and sensitivity analysis of fouling resistance in phosphoric acid/steam heat exchanger using artificial neural networks and regression methods. Sci Rep. 2023 Oct 19; 13(1):17889. doi: 10.1038/s41598-023-44516-6. PMID: 37857645; PMCID: PMC10587106.

[7] Kazi NS. Fouling and Fouling Mitigation on Heat Exchanger Surfaces. In: InTech; 2012. doi: 10.5772/32990.

[8] Sundar S, Rajagopal MC, Zhao H, Kuntumalla G, Meng Y, Chang HC, Shao C, Ferreira P, Miljkovic N, Sinha S, Salapaka S. Fouling modeling and prediction approach for heat exchangers using deep learning. Int J Heat Mass Transfer. 2020; 159:120112.

[9] Kostoglou M, Andritsos N, Karabelas AJ. Flow of supersaturated solutions in pipes. Modelling bulk precipitation and scale formation. Chem Eng Commun. 1995; 133:107-133.

[10] Amjad Z. Calcium Sulfate Dihydrate (Gypsum) Scale Formation on Heat Exchanger Surface: The Influence of Scale Inhibitors. J Colloid Interface Sci. 1988; 132(2).

[11] Sheikholeslami R. Nucleation and Kinetics of Mixed Salts in Scaling. AIChE J. 2003; 49(January):194-202.

[12] Sheikholeslami R. Calcium Sulfate Fouling - Precipitation or Particulate; A Proposed Composite Model. Heat Transfer Eng. 2000; 21(2):24-33.

[13] Taberok J, Ritter RB, Palen JW. Heat Transfer; Fouling: The Major Unresolved Problem in Heat Transfer. Chem Eng Prog. 1972; 68(2):59-67.

[14] Kho T, Muller-Steinhagen H. An experimental and numerical investigation of heat transfer fouling and fluid flow in flat plate heat exchangers. Trans IChemE, Part A. 1999; 77:124-130.Bott TR.

[15] Fouling of Heat Exchangers. ELSEVIER science BV. 1995.

[16] Bailey K. Optimise Heat Exchanger Operations By Minimising Fouling. Hydrocarbon Process. 1999 Jul; 113-127.

[17] Epstein N. Fouling in Heat Exchangers. In Proceedings of the 2nd International Conference Heat Transfer. 1978.

[18] Muller-Steinhagen H, Zhao Q, Helali-Zadeh A, Ren XG. The effect surface properties of CaSO4 scale formation during convective heat transfer and subcooled flow boiling. Can J Chem Eng. 2000 Feb; 78:12-20.

[19] Mukherjee, R., Conquer heat exchanger fouling. Hydrocarbon Processing. 1996; 121-127.

Contamination in Heat Exchangers: Types, Energy Effects and Prevention Methods

Affiliation

要約

数字