Simulations of safety vales for fluid power systems

• Autorzy: Domagała Mariusz , Momeni Hassan , Fabiś-Domagała Joanna , Filo Grzegorz , Lempa Paweł

Identyfikatory

DOI

10.2478/czoto-2019-0085

• Konferencja: 7th International Conference System Safety: Human - Technical Facility - Environment, CzOTO 2018 (7 ; 12-14.12.2018 ; Zakopane, Poland)
• Języki publikacji: EN

Abstrakty

EN

Hydraulic power systems are widely used in heavy machinery. Safety of such a systems have a major importance due to the fact that any failure may cause environmental contamination or serious injury. One of the component which protects hydraulic drive systems against excessive rising of working pressure is a safety valve which aim is to maintain pressure in the systems below acceptable level. Pressure control valves which plays important role in a hydraulic systems may have very simple or complex structure. Even in case of the simplest structure of such valve modeling is not an easy task. The new quality in designing hydraulic valves bring CFD method and FSI (Fluid Structure Interaction) methods.

Słowa kluczowe

EN

hydraulic power system; CFD; fluid structure interaction; FSI

PL

układ hydrauliczny; CFD; interakcja struktury płynu; FSI

• Wydawca: De Gruyter
• Czasopismo: System Safety : Human - Technical Facility - Environment
• Rocznik: 2019
• Tom: Vol. 1, nr 1
• Strony: 670--677
• Opis fizyczny: Bibliogr. 43 poz., rys.

Twórcy

autor

Domagała Mariusz

• Cracow University of Technology, Poland

autor

Momeni Hassan

• Western Norway University of Applied Sciences, Norway

autor

Fabiś-Domagała Joanna

• Cracow University of Technology, Poland

autor

Filo Grzegorz

• Cracow University of Technology, Poland

autor

Lempa Paweł

• Cracow University of Technology, Poland

Bibliografia

• [1] Baussan, E. et al., 2014. Neutrino super beam based on a superconducting proton linac. Phys. Rev. Spec. Top.-Accel. Beams, 17, art. 031001.
• [2] Beune, A., Kuerten, J.G.M., van Heumen, M.P.C., 2012. CFD analysis with fluid– structure interaction of opening high-pressure safety valves. Comput. Fluids, 64, 108-116.
• [3] Domagala M., 2008. CFD analysis of pilot operated relief valve. Technical Transactions – Mechanics, z. 3-M, 23-29.
• [4] Domagala M., 2015. Modelling of direct acting relief valve using CFD-FSI simulation. Technical Transactions – Mechanics, z. 2-M, 43-48.
• [5] Domagala M., 2016. Lattice-Boltzman method in CFD modelling of direct acting relief valve. Technical Transactions – Mechanics, z. 4-M, 101-106.
• [6] Domagala, M., Momeni, H., Domagala-Fabis, J., Filo, G., Krawczyk, M., 2018a, Simulation of Particle Erosion in a Hydraulic Valve. Mater. Res. Proc. 5, 17-24.
• [7] Domagala, M., Momein, H., Domagala-Fabis, J., Filo, G., Kwiatkowski, D., 2018b, Simulation of Cavitation Erosion in a Hydraulic Valve. Mater. Res. Proc. 5, 1-6.
• [8] Dwornicka, R., Radek, N., Krawczyk, M., Osocha, P., Pobedza, J., 2017. The laser textured surfaces of the silicon carbide analyzed with the bootstrapped tribology model. Metal 2017: 26th Int. Conf. Metallurgy and Materials, Ostrava, Tanger, 1252- 1257.
• [9] Fabis-Domagala, J., 2011. FMEA analysis of hydraulic drives using indexed color mode. Technical Transactions – Mechanics, z. 4-M1, 2011
• [10] Fabis-Domagala J., Filo G., Momeni H., Domagala M., 2018. Instruments of identification of hydraulic components potential failures. MATEC Web of Conferences 183, art. 03008.
• [11] Gadek-Moszczak, A., 2017. History of stereology. Image Anal. Stereol., 36, 151-152.
• [12] Gadek-Moszczak, A., Matusiewicz, P., 2017. Polish stereology – a historical review. Image Anal. Stereol., 36, 207-221.
• [13] Goroshko, A., Royzman, V., 2015. Statistical methods for providing the stability of the solutions of inverse problems and their application to decrease rotor vibroactivity. Journal of Machinery Manufacture and Reliability, 44, 232-238.
• [14] Guzowski A., Sobczyk A., 2014. Reconstruction of Hydrostatic Drive and Control System Dedicated for Small Mobile Platform. ASME – Fluid Power Systems Technology, 8th FPNI Ph.D Symposium on Fluid Power, art. V001T05A012.
• [15] Klimecka-Tatar, D., Pawłowska, G., Sozańska, M., 2015. The effect of powder particle biencapsulation with Ni-P layer on local corrosion of bonded Nd-(Fe,Co)-B magnetic material. Arch. Metall. Mater., 60, 153-157.
• [16] Kozien, E., Kozien, M.S., 2017a. Interval analysis as a method of measurement of uncertainity in the check-list method applied to identification of stage phase of companies. 26th Int. Sci. Conf. Economic and Social Development – Building Resilient Society: Economic and Social Development. Varazdin Development & Entrepreneurship Agency, Varazdin, Croatia, 210-215.
• [17] Kozien, E., Kozien, A., 2017. Commercialization of scientific research results and transfer knowledge and technologies to economy as determinants of development of universities and enterprises in Poland – legal and economic perspective. 26th Int. Sci. Conf. Economic and Social Development – Building Resilient Society: Economic and Social Development. Varazdin Development & Entrepreneurship Agency, Varazdin, Croatia, 326-335.
• [18] Krawczyk, J., Sobczyk, A., Stryczek, J., Walczak, P., 2018. Tests of New Methods of Manufacturing Elements for Water Hydraulics. Mater. Res. Proc., 5, 200-205.
• [19] Lisowski E., Filo G., Rajda J., 2015. Pressure compensation using flow forces in a multi-section proportional directional control valve. Energy Convers. Manag., 103, 1052-1064.
• [20] Lisowski E., Filo G., 2016. CFD analysis of the characteristics of a proportional flow control valve with an innovative opening shape. Energy Convers. Manag., 123, 15-28.
• [21] E., Filo G., Rajda J., 2018. Analysis of flow forces in the initial phase of throttle gap opening in a proportional control valve. Flow Meas. Instrum., 59, 157-167.
• [22] Maszke, A., Dwornicka, R., Ulewicz, R., 2018, Problems in the implementation of the lean concept at a steel works – case study. MATEC Web Conf., 183, art. 01014.
• [23] Montgomery, D.C., 2008. Design of experiments. Wiley, New York.
• [24] Pietraszek, J., Gadek-Moszczak, A., Torunski, T., 2014. Modeling of errors counting system for PCB soldered in the wave soldering technology. Adv. Mater. Res.- Switz., 874, 139-143.
• [25] Pietraszek, J., Skrzypczak-Pietraszek, E., 2014. The optimization of the technological process with the fuzzy regression. Adv. Mater. Res.-Switz., 874, 151-155.
• [26] Pietraszek, J., Kolomycki, M., Szczotok, A., Dwornicka, R., 2016. The fuzzy Approach to assessment of ANOVA results. ICCCI 2016: Computational Collective Intelligence, Lecture Notes in Artificial Intelligence, Springer, 260–268.
• [27] Pietraszek, J., Dwornicka, R., Krawczyk, M., Kołomycki, M., 2017a. The nonparametric approach to the quantification of the uncertainty in the design of experiments modelling. UNCECOMP 2017, NTU of Athens, 598-604.
• [28] Pietraszek, J., Szczotok, A., Kołomycki, M., Radek, N., Kozien, E., 2017b. Nonparametric assessment of the uncertainty in the analysis of the airfoil blade traces. Metal 2017: 26th Int. Conf. Metallurgy and Materials, Ostrava, Tanger, 1412-1418.
• [29] Pobedza, J., Sobczyk, A., 2013. Modern Coating Used in High Pressure Water Hydraulic Components. Key Engineering Materials, 542, 143-155.
• [30] Pobedza, J., Sobczyk, A., 2014. Properties of high pressure water hydraulic components with modern coatings. Adv. Mat. Res.-Switz., 849, 100-107.
• [31] Radek, N., Szczotok, A., Gadek-Moszczak, A., Dwornicka, R., Broncek, J., Pietraszek, J., 2018a. The impact of laser processing parameters on the properties of electro-spark deposited coatings. Arch. Metall. Mater., 63, 809-816.
• [32] Radek, N., Pietraszek, J., Szczotok, A., 2018b. Microstructure and tribological properties of esd coatings after laser processing. Mater. Res. Proc. 5, 206-209.
• [33] Scendo, M., Trela, J., Radek, N., 2014. Influence of laser power on the corrosive resistance of WC-Cu coating. Surf. Coat. Tech., 259, 401-407.
• [34] Singh, B. et al., 2016. Feasibility studies of time-like proton electromagnetic form factors at PANDA at FAIR. Eur. Phys. J. A, 52, art. 325.
• [35] Singh, B. et al., 2017. Feasibility study for the measurement of pi N transition distribution amplitudes at (P)over-barANDA in (P)over-barp -> J/psi pi(0). Phys. Rev. D. 95, 3, 25 p., art. 032003.
• [36] Skrzypczak-Pietraszek, E., Pietraszek, J., 2009. Phenolic acids in in vitro cultures of Exacum affine Balf. f. Acta Biol. Cracov. Bot., 51, 62-62.
• [37] Skrzypczak-Pietraszek, E., Kwiecien, I., Goldyn, A., Pietraszek, J., 2017. HPLC-DAD analysis of arbutin produced from hydroquinone in a biotransformation process in Origanum majorana L. shoot culture. Phytochem. Lett., 20, 443-448.
• [38] Skrzypczak-Pietraszek, E., Piska, K., Pietraszek, J., 2018a. Enhanced production of the pharmaceutically important polyphenolic compounds in Vitex agnus castus L. shoot cultures by precursor feeding strategy. Eng. Life Sci., 18, 287-297.
• [39] Skrzypczak-Pietraszek, E., Reiss, K., Zmudzki, P., Pietraszek, J., 2018b. Enhanced accumulation of harpagide and 8-O-acetyl-harpagide in Melittis melissophyllum L. agitated shoot cultures analyzed by UPLC-MS/MS. PLoS ONE 13, art. e0202556.
• [40] Styrylska, T., Pietraszek, J., 1992. Numerical modeling of non-steady-state temperature-fields with supplementary data. Z. Angew. Math. Mech. 72, T537- T539.
• [41] Walczak, P., Sobczyk A., 2014. Simulation of water hydraulic control system of francis turbine. ASME – Fluid Power Systems Technology, 8th FPNI Ph.D Symposium on Fluid Power, art. V001T04A001.
• [42] Ulewicz, R., 2016. Quality Management System operation in the woodworking industry. Int. Conf. Path Forward for wood products: a global perspective. Proc. of Sci. Papers, Zagreb, WOODEMA, 51-56.
• [43] Ulewicz, R., Selejdak, J., Borkowski, S., Jagusiak-Kocik, M., 2013. Process management in the cast iron foundry. Metal 2013: 22nd Int. Conf. Metallurgy and Materials, Ostrava, Tanger, 1926-1931.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).