Wydawnictwo
AWSGE
AWSGE
Akademia Nauk Stosowanych
WSGE
im. Alcide De Gasperi
WSGE
im. Alcide De Gasperi
BOOK CHAPTER (97-105)
Modelowanie numeryczne
konstrukcji zasobnika ciepła
| 1 | Politechnika Śląska Zespół Energetyki Procesowej, Katedra Metalurgii, Katowice. |
ABSTRACT
Abstract. Numerical optimization of construction battery heat to cooperate the
solar collector. Renewable energy efÞ ciency is dependent on the solution of problems of its collection and transmission, and thus the choice of optimal battery
construction. In this work focuses on numerical optimization of selected design
of thermal energy storage for use with solar collector. Ideas of the authors is to
develop a concept relatively easy to make and cheap battery underß oor heating.
REFERENCES (13)
1.
Thirugnanasambandam M., Iniyan S., Goic R.; A review of solar thermal technologies, Renewable and Sustainable Energy Reviews, 14 (2010).
2.
Bałys M.R., Buczek B.; Akumulacja ciepła w monolitach węglowych dlamagazynowania energii – rozważania modelowe, Polityka energetyczna 12(2009).
3.
Wita A., Balcerzak A., Mirosław-Świątek D., System grzewczy z gruntowym akumulatorem energii cieplnej - wyniki eksperymentów, XIV Konferencja naukowa – metody komputerowe w projektowaniu i analizie konstrukcji hydrotechnicznych, Korbielów 2002.
4.
Vaivudh S., Rakwichian W., Chindaruksa S., Heat transfer of high thermal energy storage with heat exchanger for solar trough power plant, Energy Conversion and Management 49 (2008).
5.
Zheng D., Cao W., Retrofitting for DME process by energy-flow framework diagram, Chemical Engineering and Processing 46 (2007).
6.
Schmidt T., Mangold D., Müller-Steinhagen H., Central solar heating plants with seasonal storage in Germany, Solar Energy 76 (2004).
7.
Raab S., Mangold D., Müller-Steinhagen H., Validation of a computer model for solar assisted district heating systems with seasonal hot water heat store, Solar Energy 79 (2005).
8.
Ming T., Liu W., Pan Y., Xu G., Numerical analysis of flow and heat transfer characteristics in solar chimney power plants with energy storage layer, Energy Conversion and Management 49 (2008).
9.
Pahud D., Central solar heating plants with seasonal duct storage and short-term water storage: design guidelines obtained by dynamic system simulations, Solar Energy 69 (2000) 495–509.
10.
Ohga H., Mikoda K., Energy performance of borehole thermal energy storage systems. Proceedings of Seventh International IBPSA Conference, Rio de Janeiro (2001).
11.
Lin M.C., Chun L.J., Lee W.S., Chen S.L., Thermal performance of a two-phase thermosyphon energy storage system, Solar Energy 75 (2003).
12.
Denholm P., Kulcinski G.L., Life cycle energy requirements and greenhouse gas emissions from large scale energy storage systems, Energy Conversion and Management 45 (2004).
13.
Ragoonanan V., Davidson J.H., Homan K.O., Mantell S.C., The benefit of dividing an indirect thermal storage into two compartments: Discharge experiments, Solar Energy 80 (2006).
We process personal data collected when visiting the website. The function of obtaining information about users and their behavior is carried out by voluntarily entered information in forms and saving cookies in end devices. Data, including cookies, are used to provide services, improve the user experience and to analyze the traffic in accordance with the Privacy policy. Data are also collected and processed by Google Analytics tool (more).
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
