Current issue
Archive
About the Journal
About
Editorial Board
Abstract & Indexing
Contact
Editorial Policies
Authorship & COI
Ethical principles
Principles of Transparent Checklist
Open access
For Authors
Instructions to Authors
Detailing Guidelines for Authors
Review process
Review sheet
How to submit
Open Access license
ORIGINAL PAPER
Analysis of Forced Spatial Vibrations of a Centrifugal Pump Impeller with Axial Forces Balancing Device
1
Department of General Mechanics and Machine Dynamics, Sumy State University, 2 Rimsky-Korsakov Str., Sumy 40007, Ukraine
2
Faculty of Mechatronics and Machine Design, Kielce University of Technology, Al. 1000-lecia PP 7, 25-314 Kielce, Poland
Online publication date: 2016-09-10
Publication date: 2016-08-01
International Journal of Applied Mechanics and Engineering 2016;21(3):737-750
KEYWORDS
ABSTRACT
In this paper, a model of a pump impeller with annular seals and a balancing device, used as a combined support-seal assembly, is considered. The forced coupled radial, angular and axial vibrations of the rotor are determined with consideration of linearized inertial, damping, gyroscopic, positional and circulating forces and moments acting on the impeller from the side of the fluid flow in annular seals. The theoretical analysis is supplemented with a numerical example, the amplitude frequency characteristics are shown.
REFERENCES (32)
1.
Childs D.W. (1993): Turbomachinery Rotordynamics Phenomena, Modeling, and Analysis. – John Wiley and Sons, Inc.
2.
Childs D.W. (1993). Turbomachinery Rotordynamics Phenomena, Modeling, and Analysis. John Wiley and Sons, Inc.
3.
San Andres L. (1993): Dynamic force and moment coefficients for short length annular seals. – ASME Journal of Tribology, vol.115, No.1, pp.61-70.
4.
San Andres L. (1993). Dynamic force and moment coefficients for short length annular seals ASME Journal of Tribology. 115 (1): 61-70.
5.
Gosiewski Z. (2008): Analysis of coupling mechanism in lateral/torsional rotor vibrations. – Journal of Theoretical and Applied Mechanics, vol.46, No.4, pp.829-844.
6.
Gosiewski Z. (2008). Analysis of coupling mechanism in lateral/torsional rotor vibrations Journal of Theoretical and Applied Mechanics. 46 (4): 829-844.
7.
Cheng M., Meng G. and Jing J. (2006): Non-linear dynamics of rotor-bearing-seal system. – Archive of Applied Mechanics, vol.76, pp. 215-227.
8.
Cheng M., Meng G., Jing J. (2006). Non-linear dynamics of rotor-bearing-seal system Archive of Applied Mechanics. 76: 215-227.
9.
Li W., Yang Y., Sheng D. and Chen J. (2011): A novel nonlinear model of rotor/bearing/seal system and numerical analysis. – Mechanism and Machine Theory, No.46, pp.618–631.
10.
Li W., Yang Y., Sheng D., Chen J. (2011). A novel nonlinear model of rotor/bearing/seal system and numerical analysis Mechanism and Machine Theory. (46): 618-631.
11.
Faria M.T.C. and Miranda W.M. (2012): Pressure dam influence on the performance of gas face seals. – Tribology International, No.47, pp.134–141.
12.
Faria M.T.C., Miranda W.M. (2012). Pressure dam influence on the performance of gas face seals Tribology International. (47): 134-141.
13.
Muszynska A. and Bently D.E. (1990): Frequency-swept rotating input perturbation techniques and identification of the fluid force models in rotor/bearing/seal systems and fluid handling machines. – Journal of Sound and Vibration, vol.143, No.1, pp.103–124.
14.
Muszynska A., Bently D.E. (1990). Frequency-swept rotating input perturbation techniques and identification of the fluid force models in rotor/bearing/seal systems and fluid handling machines Journal of Sound and Vibration. 143 (1): 103-124.
15.
Kundera C. and Martsinkovsky V.A. (2014): Static and dynamic analysis of a pump impeller with a balancing device. Part I: Static analysis. – Int. J. of Applied Mechanics and Engineering, vol.19, No.3, pp.609-619.
16.
Kundera C., Martsinkovsky V.A. (2014). Static and dynamic analysis of a pump impeller with a balancing device. Part I: Static analysis Int. J. of Applied Mechanics and Engineering. 19 (3): 609-619.
17.
Martsinkovsky V.A., Zhulyov A. and Kundera C. (2014): Static and dynamic analysis of a pump impeller with a balancing device. Part II: Dynamic analysis. – Int. J. of Applied Mechanics and Engineering, vol.19, No.3, pp.621-631.
18.
Martsinkovsky V.A., Zhulyov A., Kundera C. (2014). Static and dynamic analysis of a pump impeller with a balancing device. Part II: Dynamic analysis Int. J. of Applied Mechanics and Engineering. 19 (3): 621-631.
19.
Martsinkovsky V.A. (2012): Rotordynamics of centrifugal machines (in Russian). – Editorial of the Sumy State University, Sumy.
20.
Martsinkovsky V.A. (2012). Rotordynamics of centrifugal machines. Editorial of the Sumy State University, Sumy. (in Russian).
21.
Marcinkowski W.A. and Kundera C. (2008): Design theory of noncontacting seals (in Polish). – Editorial of the Kielce University of Technology, Kielce.
22.
Marcinkowski W.A., Kundera C. (2008). Design theory of noncontacting seals. Editorial of the Kielce University of Technology, Kielce. (in Polish).
23.
Korczak A. (2005): Investigations of systems counterbalancing the axial thrust in multi-stage centrifugal pumps (in Polish). – Scientific Book of the Silesian University of Technology, No.1679, Gliwice.
24.
Korczak A. (2005). Investigations of systems counterbalancing the axial thrust in multi-stage centrifugal pumps. Scientific Book of the Silesian University of Technology, Gliwice. No.1679,.
27.
Martsinkovsky V.A., Demin S.I., Gulyj A.N. and Bachkina A.A. (1995): Centrifugal pump. – Patent SU1771248.
28.
Martsinkovsky V.A., Demin S.I., Gulyj A.N., Bachkina A.A. (1995). Centrifugal pump. Patent SU1771248.
31.
Chiba Y., Ishikawa Ch., Katsura H. and Abe D. (2007): Single-shaft multistage pump. – Patent US7198457B2.
32.
Chiba Y., Ishikawa Ch., Katsura H., Abe D. (2007). Single-shaft multistage pump. Patent US7198457B2.
| eISSN: | 2353-9003 |
| ISSN: | 1734-4492 |
Task: edition of a scientific journal, its internationalization and ensuring open access to the journal via the Internet
© 2006-2024 Journal hosting platform by Bentus
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.
