79 

 

REFERENCES 

(1) Peng Z., Kessissoglou N., "An integrated approach to fault diagnosis of 

machinery using wear debris and vibration analysis", Wear Vol. 255 (2003), 

pp. 1221–1232. 

 

(2) Ebersbach S., Peng Z., Kessissoglou N. J., "The investigation of the condition 

and faults of a spur gearbox using vibration and wear debris analysis 

techniques", Wear Vol.  260 (2006), pp. 16–24. 

 

(3) Roylance B. J., Williams J. A., & Dwyer-Joyce R., “Wear debris and 

associated wear phenomena – fundamental research and practice”, Vol. 214 

(2000), pp. 79-105. 

 

(4) Williams J. A., “Wear and wear particles – Some fundamentals”, Wear, Vol. 

38 (2005), pp. 863- 870. 

 

(5) Seifert W. W., & Westcott V. C., “A method for the study of wear particles in 

lubricating oil,” Wear, Vol. 21 (1972), pp. 27- 42. 

 

(6) Zum Gahr K. H., “Modeling of two body abrasive wear,” Wear, Vol. 127 

(1988), pp. 87- 103. 

 

(7) Anderson D.P., “Wear Particles Atlas,” Revised ed., Report NAEC, (1982), 

pp. 92-163. 

 

(8) Roayalance B. J., Albidewi I. A., Laghari M. S., Luxmoore A. R., & Deravi 

F., “Computer Aided Vison Engineering,(CAVE)- Quantification of wear 

particle morphology”, Vol. 50 (1993), pp. 111-116. 

 

(9) Barron T., “Engineering Condition Monitoring,” Addison-Wesley, Reading, 

MA, UK 1996. 

 

(10) Hunt T.M., “Handbook of Wear Debris Analysis and Particle Detection in 

Liquids”, Elsevier Science Publishers LTD., Essex, England, (1993). 

 

 



80 

 

(11) Neale M.J., and Woodley B.J., “A guide to the condition monitoring of 

machinery”. Report TRD 223 for the British Department of Industry (1978). 

 

(12) IEEE draft standard P1438/D1.5 “Guide for Applications of Plant Condition 

Monitoring for Hydroelectric Facilities”. Section 4.3 ‘Potential Benefits’ 

(1999). 

 

(13) McMillan D., and Ault G.W., “Condition monitoring benefit for onshore 

wind turbines sensitivity to operational parameters”. IET Renewable Power 

Generation, Vol. 2 (2008), pp. 60–72. 

 

(14) Wang L., Gao, Robert X., “Condition Monitoring and Control for Intelligent 

Manufacturing”, Springer, (2006). 

 

(15) Coverdell Andy., Noria Corporation, “Acid Number Test Reproducibility and 

Repeatability”, Practicing Oil Analysis, (2006). 

 

(16) Muszynska A., “Rotor dynamics”, CRC Press, (2005).  

(17) Carden Peter E., Fanning Paul, “Vibration Based Condition Monitoring”, 

SHM, Vol. 3, (2004), pp. 355-377. 

 

(18) Peng Z., Kessissoglou N.J., Cox M., “A study of the effect of contaminant 

particles in lubricants using wear debris and vibration condition monitoring 

techniques”, Wear Vol. 258, (2005), pp. 1651-1662. 

 

(19) Keith Mobley R., "An Introduction to Predictive Maintenance", Second 

Edition, Amsterdam; Boston: Elsevier/Butterworth Heinemann, (2002). 

 

(20) Peng Z., Kessissoglou N.J., Cox, M., “A study of the effect of contaminant 

particles in lubricants using wear debris and vibration condition monitoring 

techniques”, Wear Vol. 258, (2005), pp. 1651-1662. 

 

(21) Courrech J., “Examples of the Application of Gated Vibration Analysis for 

the Detection of Faults in Reciprocating Machines,” Noise and Vibration 89 

Conference, Singapore, 16
th

 – 18
th

 August, 1989.  



81 

 

(22) Downham E., and Woods R., “The Rationale of Monitoring Vibration in 

Rotating Machinery in Continuously Operating Process Plant,” ASME paper 

no. 71, Vibration-96, (1971), pp. 54-59. 

 

(23) Bate A. H., “Vibration Diagnostics for Industrial Electric Motor-Drives,” 

Brüel and Kjaer application note. 

 

(24) Roylance B.J., and Hunt T.M., “The Wear Debris Analysis Handbook”. 

Coxmoor publishing Company, Oxford, UK (1999). 

 

(25) Parikka R., and Vaajoensuu E., Valon läpäisyyn perustuvat low cost-

analysaattorit öljyjen käynninaikaiseen kunnonvalvontaan. Tribologia – 

Finnish Journal of Tribology Vol. 22, (2003), pp. 16–22.  

 

(26) Toms L.A., “Machinery Oil Analysis – Methods, Automation & Benefits”. 

Coastal Skills Training, Virginia Beach, USA (1998). 

 

(27) Rao BKN Handbook of Condition Monitoring. Elsevier Science Ltd, Oxford, 

UK (1996).  

 

(28) Hägg B., “The great profitability potential in manufacturing industry”. In: 

Lahdelma S., & Palokangas K., (eds) Proc of the 2nd Int Seminar of 

Maintenance, Condition Monitoring and Diagnostics, Oulu, Finland, 28th – 

29th September 2005, pp. 7–16. 

 

(29) Maxwell H., Johnson B., “Vibration and lube oil analysis in an integrated 

predictive maintenance program”, in: Proceedings of the 21st Annual 

Meeting of the Vibration Institute (1997), pp. 117–124. 

 

(30) Ahlroos T Tribologia, voitelu ja ympäristöasiat. Tribologia – Finnish Journal 

of Tribology Vol. 22 (2003), pp. 23–29. 

 

(31) Hunt T., Evans J., Oil Analysis Handbook. Coxmoor publishing company, 

Oxford, UK (2004). 

 

(32) SKF Vibration Diagnostic Guide 

(www.skf.com/medialibrary/asset/0901d19680218bf8, 27
th

 September 2013) 

http://www.skf.com/medialibrary/asset/0901d19680218bf8


82 

 

APPENDICES  

Features of vibration analyzer               Appendix - A 



83 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



84 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



85 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



86 

 

SEPARATOR 500              Appendix - B 

Vibration results: - Point (A), Side of mid bearing of vertical shaft 

 

Vibration results: - Point (B), Front of mid bearing of vertical shaft

 

Vibration results: - Point (C), Side of lower bearing of vertical shaft

 
 



87 

 

Vibration Results: - Point (D), Axial of lower bearing of vertical shaft 

 

Vibration Results: - Point (E), Non driven end of the motor housing (Vertical)

 

Vibration Results: - Point (F), Non driven end of the motor housing (Horizontal)

 



88 

 

Vibration Results: - Point (G), Driven end of the motor housing (Vertical) 

 

Vibration Results: - Point (H), Driven end of the motor housing (Horizontal)

 

Vibration Results: - Point (I), Driven end of the motor housing (Axial)

 



89 

 

SEPARATOR 300 

Vibration results: - Point (A), Side of mid bearing of vertical shaft

 

Vibration results: - Point (B), Front of mid bearing of vertical shaft

 

Vibration results: - Point (C), Side of lower bearing of vertical shaft 

 



90 

 

Vibration results: - Point (D), Axial of lower bearing of vertical shaft 

 

Vibration Results: - Point (E), Non driven end of the motor housing (Vertical)

 

Vibration results: - Point (F), Non driven end of the motor housing (Horizontal) 



91 

 

Vibration results: - Point (G), Driven end of the motor housing (Vertical) 

 

Vibration results: - Point (H), Driven end of the motor housing (Horizontal)

 

Vibration results: - Point (I), Driven end of the motor housing (Axial)

 



92 

 

Properties of Rando 220             Appendix - C 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

 

 

 

 

 

 

 

 

 



93 

 

Results of oil analysis             Appendix - D 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



94