Identyfikatory
Warianty tytułu
Control Valve with Constant Value of the Inner Authority
Języki publikacji
Abstrakty
W artykule zaprezentowano propozycję nowego podejścia do projektowania i wymiarowania powszechnie stosowanych w instalacjach grzewczych zaworów regulacyjnych podwójnej regulacji, pozwalające zachować stałą wartość autorytetu wewnętrznego i tym samym zachować stałą postać charakterystyki regulacyjnej, niezależnie od wartości nastawienia wstępnego zaworu.
The article proposes a new approach to the design and dimensioning of commonly used in heating systems control valves of dual regulation, allowing to maintain constant internal authority and thereby retain the unchanged control characteristic, regardless of the value of the valve pre-setting.
Wydawca
Czasopismo
Rocznik
Tom
Strony
9--15
Opis fizyczny
Bibliogr. 42 poz., rys., tab., wykr.
Twórcy
autor
- Instytut Maszyn i Urządzeń Energetycznych, Wydział Mechaniczny, Politechnika Krakowska
Bibliografia
- [1] Adolph M., N. Kopraann, B. Lupulescu, D. Muller. 2014. „Adaptive control strategies for single room heating", Energy and Buildings (68) :771-778.
- [2] Afram A., F. Janabi-Sharifi. 2014. „Theory and applications of HVAC control systems - A review of model predictive control (MPC)", Building and Environment 72(2): 343-355.
- [3] Baia J., S. Wangb, X. Zhangc. 2008. „Development of an adaptive Smith predictor-based self-tuning PI controller for an HVAC system in a test room", Energy and Buildings (40): 2244-2252.
- [4] Bojić M., M. Miletić, J. Maleśević, S. Djordjević, D. Cvetković. 2012. „Influence of additional storey construction to space heating of aresidential building", Energy and Buildings (54) : 511-518.
- [5] Bojic M., N. Trifunovic. 2002. „Linear programming optimization of heat distribution in a district-heating system by valve adjustments and substation retrofit", Building andEnvironment 35 (2): 151-159.
- [6] Chen Y., S. Treado. 2014. „Development of a simulation platform based on dynamie models for HVAC control analysis", Energy and Buildings (68) : 376-386.
- [7] Gamberi M, R. Manzini, A. Regattieri. 2009. „Simulink© simulator for building hydronic heating systems using the Newton-Raphson algorithm", Energy and Buildings, 41, (2009), pp. 848-855.
- [8] Gruber M„ A. Triischel, J. O. Dalenback. 2014. „Model-based controllers for indoor climate control in office buildings-Complexity and performance evaluation", Energy and Buildings (68): 213-222.
- [9] Hasan A., J. Kurnitski, K. Jokiranta. 2009. „A combined Iow temperaturę water heating system consisting of radiators and floor heating", Energy and Buildings (41) : 470-479.
- [10] Henzea G. P., A. G. Flossb. 2011. „Evaluation of temperature degradation in hydraulic flow networks", Energy and Buildings (43) : 1820-1828,
- [11] Huchtemann K., D. Muller. 2013. „Simulation study on supply temperature optimization in domestic heat pump systems", Building and Environment 59 (1): 327-335.
- [12] Ippolito M.G., E. R. Sanseverino, G. Zizzo. 2014. „Impact of building automation control systems and technical building management systems on the energy performance class of residential buildings: An Italian case study", Energy and Buildings (69): 33-40.
- [13] Karjalainen S., O. Koistinen. 2007. „User problems with individual temperature control in offices", Building and Environment 42 (8) : 2880-2887.
- [14] Karjalainen S. 2013. „Should it be automatic or manual - The occupant's perspective on the design of domestic control systems", Energy and Buildings (65) : 119-126,
- [15] Lauenburg P., J. Wollerstrand. 2014. „Adaptive control of radiator systems for a lowest possible district heating return temperature", Energy and Buildings (72): 132-140.
- [16] Leforta A., R. Bourdaisa, G. Ansanay-Alexb, H. Guéguena. 2013. „Hierarchical control method applied to energy management of a residential house", Energy and Buildings (64): 53-61.
- [17] Liao Z., M. Swainson, A. L. Dexter. 2005. „On the control of heating systems in the UK", Building and Environment 40 (3) : 343-351.
- [18] Liu L., L. Fu, Y. Jiang, S. Guo. 2010. „Maintaining uniform hydraulic conditions with intelligent on-off regulation", Building and Environment 45 (12) : 2817-2822.
- [19] Luoa M, B. Caoa, X. Zhoub, M. Lia, J. Zhangb, Q. Ouyanga, Y. Zhua. 2014. „Can personal control influence human thermal comfort? A field study in residential buildings in China in winter", Energy and Buildings (72) : 411-418.
- [20] Maivel M, J. Kurnitski. 2014. „Low temperaturę radiator heating distribution and emission efficiency in residential buildings ", Energy and Buildings (69) : 224-236.
- [21] Muniak D. 2014. „A new methodology to determine the pre-setting of the control valve in a heating installation. A generał model", Applied Energy 135 (12) : 35-42.
- [22] Muniak D. 2015. „A proposal for a new methodology to determine inner authority of the control valve in the heating system ", Applied Energy 155 (10): 421-433.
- [23] Muniak D. 2016. „Analityczna metoda wymiarowania zaworów regulacyjnych. Część I.", Ciepłownictwo, Ogrzewnictwo, Wentylacja 47 (6) : 234-240.
- [24] Muniak D. 2016. „Analityczna metoda wymiarowania zaworów regulacyjnych. Część II.", Ciepłownictwo, Ogrzewnictwo, Wentylacja 47 (7): 277-283.
- [25] Muniak D.: Armatura regulacyjna w wodnych instalacjach grzewczych, PWN, Warszawa (przyjęte do druku).
- [26] Muniak D. 2016. „Sizing the radiator control valve taking account of inner authority", Procedia Engineering (157): 98-105.
- [27] Muniak D. 2014. „Stanowisko do badań hydraulicznych charakterystyk zaworów regulacyjnych w stosowanych instalacjach wodnych", Ciepłownictwo, Ogrzewnictwo, Wentylacja 45 (8): 299-302.
- [28] Muniak D. : „Wpływ autorytetu wewnętrznego regulacyjnych zaworów grzejnikowych na ich dobór i charakterystyki hydrauliczne", Rozprawa Doktorska, Kraków 2014.
- [29] Muniak D. 2011. „Wspomaganie komputerowe równoważenia hydraulicznego instalacji centralnego ogrzewania. Część I", Ciepłownictwo, Ogrzewnictwo, Wentylacja 42 (9) :352-355.
- [30] Muniak D. 2012. „Wspomaganie komputerowe równoważenia hydraulicznego instalacji centralnego ogrzewania. Część II", Ciepłownictwo, Ogrzewnictwo, Wentylacja, 43 (11) : 480-486.
- [31] Ogonowski S. 2010. „Modeling of the heating system in smali building for control", Energy and Buildings (42) : 1510-1516.
- [32] Peeters L., J. Van der Veken, H. Hens, L. Helsen, W. D'haeseleer. 2008. „Control of heating systems in residential buildings: Current practice", Energy and Buildings (40) :1446-1455.
- [33] Peffer T., M. Pritoni, A. Meier, C. Aragon, D. Perry. 2011. „How people use thermostats in homes: A review", Building and Environment 46 (12): 2529-2541.
- [34] Pineaua D., P. Riviereb, P. Stabatb, P. Hoanga P, V. Archambaulta. 2013. „Performance analysis of heating systems for low energy houses", Energy and Buildings (65): 45-54.
- [35] Rhee K.N., M.S. Yeo, K.W Kim. 2011. „Evaluation of the control performance of hydronic radiant heating systems based on the emulation using hardware-in-the-loop simulation", Building and Environment 46(10) : 2012-2022.
- [36] Rogers D., M. Foster, C. Bingham. 2013. „A recursive modelling techniąue applied to the model predictive control of fluid filled heat emitters", Building and Environment, 62 (4): 33-44.
- [37] Samuel R. West, John K. Ward, Josh Wall. 2014. "Trial results from a model predictive control and optimisation system for commercial building HVAC", Energy and Buildings (72): 271-279.
- [38] Sun J., Reddy A. 2005. „Optimal control of building HVAC&R systems using complete simulation-based sequential quadratic programming (CSB-SQP)", Building andEnvironment, 40 (5): 657-669.
- [39] Whalley R., Abdul-Ameer A. 2011. „Heating, ventilation and air conditioning system modelling", Building and Environment 46 (3): 643-656.
- [40] Xu B., Fu L., Di. H. 2008. „Dynamie simulation of space heating systems with radiators controlled by TRVs in buildings", Energy and Buildings (40) :1755-1764.
- [41] Xu B., Huang A., Fu L., Di H. 2011. „Simulation and analysis on control effectiveness of TRVs in district heating systems", Energy and Buildings (43) :1169-1174.
- [42] Yu Y., Loftness V., Yu D. 2013. „Multi-structural fast nonlinear model-based predictive control of a hydronic heating system", Building and Environment 11 (69): 13-148.
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-2b1bed42-3601-4979-840a-2d3eeb1889ef