PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Tytuł artykułu

Water-paraffin dispersion systems: manufacturing and application

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The paper presents the study results of the stability and heat storage capacity of paraffin-in-water phase change suspensions (PCSs) obtained by the homogenization of paraffin and water in the developed rotary hydrodynamic homogenizer. The optimal concentration of components for obtaining stable paraffin-in-water suspensions is found. It is shown that the stable PCSs in the form of pastes, gels, and liquids can be obtained depending on the concentration of water, paraffin, and the surface active agent (SAA) as well as its type. In addition, the scheme of the solar heating system with the heat storage tank where the PCS functions both as the heat transfer fluid and the heat storage media is presented. It is shown that the use of PCS in the domestic solar heating system allowed the heat storage capacity of the storage tank to be increased by 25% as a result of the high fusion heat of paraffin and the high value of the water specific heat capacity. The estimation of the saving rate from applying fluid PCS as a heat storage medium is also presented and discussed.
Twórcy
  • Cherkasy State Technological University, Department of Energy Technologies 460 Shevchenko Boulevard, 18006 Cherkasy, Ukraine
  • Cherkasy State Technological University, Department of Energy Technologies 460 Shevchenko Boulevard, 18006 Cherkasy, Ukraine
  • Cherkasy State Technological University, Department of Automobiles and Technology of their Operation 460 Shevchenko Boulevard, 18006 Cherkasy, Ukraine
  • Cherkasy State Technological University, Department of Energy Technologies 460 Shevchenko Boulevard, 18006 Cherkasy, Ukraine
autor
  • Nexthorizon Sasu 12 rue de la Martelliere 38500 Vairon, France
  • University of Rostock, R&D in Renewable Energy Erich-Schlesinger Str. 20, 18059 Rostock, Germany
Bibliografia
  • [1] Huang L, Pollerberg C, Doetsch C. Paraffin in Water Suspension as heat transfer and storage medium. Fraunhofer Institute for Environmental, Safety, and Energy Technology UMSICHT (2017), 1-8.
  • [2] Kalnaes SE, Jelle BP. Phase change materials and products for building applications: A state-of-the-art review and future research opportunities. Energy and Buildings 94 (2015), 150-176.
  • [3] Shao J, Darkwa J, Kokogiannakis G. Review of Phase change suspensions (PCMEs) and their applications in HVAC systems. Energy and Buildings 94 (2015), 200-217.
  • [4] Xiyao Z, Jian-Yong W, Jianlei N. PCM-in-water suspension for solar thermal applications: The effects of emulsifiers and emulsification conditions on thermal performance, stability and rheology characteristics. Solar Energy Materials & Solar Cells 147 (2016), 211-224.
  • [5] Yovchenko AV, Bespalko SA, Poliakov SP. Obtaining heat storage suspensions that change their aggregate state. Energy management: Status and prospects of development. V International scientific-technical and educational-methodical conference (2018), 24-25.
  • [6] Reddy KS, Mudgal V, Mallick TK. Review of latent heat thermal energy storage for improved material stability and effective load management. Journal of Energy Storage 15 (2018), 205-227.
  • [7] Feliñski P, Sekret R. Effect of PCM application inside an evacuated tube collector on the thermal performance of a domestic hot water system. Energy and Buildings 152 (2017), 558-567.
  • [8] Mohamed EZ, Jun Z, Ammar HE, Farid AH, Ling M, Yanping D, Kabeel AE, Shalaby SM. Applications of cascaded phase change materials in solar water collector storage tanks: A review. Solar Energy Materials and Solar Cells 199 (2019), 24-49.
  • [9] Chen J, Zhang P. Preparation and characterization of nano-sized phase change suspensions as thermal energy storage and transport media. Applied Energy 190 (2017), 868-879.
  • [10] Khan Z, Ahmad Khan Z. Experimental and numerical investigations of nano-additives enhanced paraffin in a shell-and-tube heat exchanger: a comparative study. Applied Thermal Engineering 143 (2018), 777-790.
  • [11] Wang F, Liu J, Fang X, Zhang Z. Graphite nanoparticles-dispersed paraffin/water emulsion with enhanced thermal-physical property and photo-thermal performance. Solar Energy Materials and Solar Cells 147 (2016), 101-107.
  • [12] Wang F, Ling Z, Fang X, Zhang Z. Optimization on the photo-thermal conversion performance of graphite nanoplatelets decorated phase change material emulsions. Solar Energy Materials and Solar Cells, 186, (2018), 340-348.
  • [13] Zhang X, Wu J-Y, Niu J. PCM-in-water emulsion for solar thermal applications: the effects of emulsifiers and emulsification conditions on thermal performance, stability and rheology characteristics. Solar Energy Materials and Solar Cells 147 (2016), 211-224.
  • [14] Wang F, Fang X, Zhang Z. Preparation of phase change material emulsions with good stability and little supercooling by using a mixed polymeric emulsifier for thermal energy storage. Solar Energy Materials and Solar Cells 176 (2018), 381-390.
  • [15] Wang F, Lin W, Ling Z, Fang X. A comprehensive review on phase change material emulsions: Fabrication, characteristics, and heat transfer performance. Solar Energy Materials and Solar Cells 191 (2019), 218-234.
  • [16] Venglovsky VI. Diurnal heat storage with possible warming by built-in or external heat exchangers, Bulletin of the National University "Lviv Polytechnic": [collection of research works]: Theory and practice of construction 737 (2012), 21-25. (in Ukrainian)
  • [17] Inaba H, Dai C, Horibe A. Natural convection heat transfer of microemulsion phase-change-material slurry in rectangular cavities heated from below and cooled from above. International Journal of Heat Mass Transfer 46 (2003), 4427-4438.
  • [18] Morimoto T, Kumano H. Flow and heat transfer characteristics of phase change emulsions in a circular tube: part 1. Laminar flow. International Journal of Heat Mass Transfer 117 (2018), 887-895.
  • [19] Roy SK, Avanic BL. Laminar forced convection heat transfer with phase change material emulsions. International Communication in Heat and Mass Transfer 24 (1997), 653-662.
  • [20] Zhao Z, Wu T, Shi Y, Li L. An investigation on rheology and heat transfer characteristics for a phase change emulsion. Journal of Engineering Thermophysics 22 (2001), 589-592.
  • [21] Zhao Z, Shi Y, Zhang Y, Gai P. Flow and heat transfer characteristics of phase-change emulsion in a coiled double-tube heat exchanger. Journal of Engineering Thermophysics 23 (2002), 730-732.
  • [22] Ma F, Chen J, Zhang P. Experimental study of the hydraulic and thermal performances of nano-sized phase change emulsion in horizontal mini-tubes Energy 149 (2018), 944-953.
  • [23] Ho CJ, Lee C-Y, Yamada M. Experiments on laminar cooling characteristics of a phase change nanofluid flow through an iso-flux heated circular tube. International Journal of Heat and Mass Transfer 118, (2018), 1307-1315.
  • [24] Eunsoo C, Cho YI, Lorsch HG. Forced convection heat transfer with phase- change-material slurries: turbulent flow in a circular tube. International Journal of Heat and Mass Transfer 37 (1994), 207-215.
  • [25] Mikkola V, Puupponen S, Saari K, Ala-Nissila T, Seppala A. Thermal properties and convective heat transfer of phase changing paraffin nanofluids. International Journal of Thermal Sciences 117 (2017), 163-171.
  • [26] Saarinen S, Puupponen S, Merilainen A, Joneidi A, Seppala A, Saari K, Ala-Nissila T. Turbulent heat transfer characteristics in a circular tube and thermal properties of n-decane-in-water nanoemulsion fluids and micellesin- water fluids. International Journal of Heat and Mass Transfer 81 (2015), 246-251.
  • [27] Morimoto T, Kumano H. Flow and heat transfer characteristics of phase change emulsions in a circular tube: part 2. Turbulent flow. International Journal of Heat and Mass Transfer 117 (2018), 903-911.
  • [28] Sanfeld A, Steinchen A. Suspensions stability, from dilute to dense suspensions-role of drops deformation. Advanced Colloid Interface Science 140 (2008), 1-65.
  • [29] Golemanov K, Tcholakova S, Denkov ND, Gurkov T. Selection of surfactants for stable paraffin-in-water dispersions, undergoing solid-liquid transition of the dispersed particles. Langmuir 22 (2006), 3560-3569.
  • [30] Yovchenko AV, Bespalko SA, Poliakov SP. The use of suspensions that change their aggregate state in the heat power engineering and construction industry. Hydromechanics in engineering practice: materials of the XIV International Scientific and Technical Conference (2018), 99-104 (in Ukrainian).
  • [31] Levina KY. The use of water-bio-fuel suspensions to improve the operational and environmental performance of a diesel engine, PhD thesis (05.20.03), Tambov, (2015), 175 (in Russian).
  • [32] Abdo Khaled MA. Obtaining suspensions "water - fuel oil" and conformity of change in their properties with a change in composition, PhD thesis, Moscow (2007), 136 (in Russian).
  • [33] Ravelet F, Delfos R, Westerweel J. Influence of global rotation and Reynolds number on the large-scale features of a turbulent Taylor-Couette flow. Physics of Fluids 22 (2010), 055103.
  • [34] Pereverzev AN, Bohdanov NF, Roshchin YN. Paraffin production, Moscow, Himia (1973), 224.
  • [35] https://www.products.pcc.eu (accessed July 21, 2020)
  • [36] The HLB system: a time-saving guide to emulsifier selection. Anticipating needs. https://www.academia.edu/24755447/The HLB SYSTEM a timesaving guide to emulsifier selection ANTICIPATING NEEDS (accessed July 21, 2020)
  • [37] https://www.pharmencyclopedia.com.ua/article/891/polisorbati (accessed July 21, 2020)
  • [38] Lee T-W. Thermal and Flow Measurements CRC Press 2008.
  • [39] Persson U, Wiechers E, Moller B, Werner S. Heat Roadmap Europe: Heat distribution costs. Energy 176 (2019), 604-622.
  • [40] https://tariffs.ib-net.org/sites/IBNET/Map (accessed July 21, 2020)
  • [41] https://www.alibaba.com/product-detail/Chemical-raw-materials-Octacosane-630-02_1600071165687.html?spm=a2700.galleryofferlist.0.0.60787400BPwcf2 (accessed July 21, 2020)
  • [42] https://www.alibaba.com/product-detail/2019-Hot-Sale-Emulsifier-antistaticagent_62237374123.html?spm=a2700.7724857.normalList.279.727f58f9YzYrGZ (accessed July 21, 2020)
  • [43] https://www.alibaba.com/product-detail/NT-ITRADE-emulsifier-CAS-No-1338_62487084478.html?spm=a2700.7724857.normalList.45.17ab6f9f60FxT1 (accessed July 21, 2020)
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-5c441759-bd9b-40ec-846a-e2dba2f2e68b
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.