A Conductivity-Based Sensor for Detecting Micro-Water in On-Line Oil Analysis

Tong Hai Wu; Ren Jie Gong; Xiao Gang Zhang; Chen Xing Sheng

doi:10.4028/www.scientific.net/AMR.850-851.279

Paper Titles

Contact Analysis between Packer Slips and Casing Based on Abaqus
p.262

Resonant Pavement Breaker Vibration System Design and Simulation
p.266

A Study on Cathodic Protection Current Density on Rebar in Onshore Concrete Structure of Persian Gulf
p.270

High Speed Dynamic Characteristics Research for LL680 Flexible Rapier Loom
p.274

A Conductivity-Based Sensor for Detecting Micro-Water in On-Line Oil Analysis
p.279

Design and Simulation of Brushless Direct Current Motor Drive
p.284

Optimal Design of Hydraulic Umbrella Drilling Rig Based on Finite Element Analysis
p.288

Optimization Design Study on a New Type Underwater Turbine Engine
p.292

Reason Analysis and Repair Measures of Cracked Die
p.296

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 850-851A Conductivity-Based Sensor for Detecting...

A Conductivity-Based Sensor for Detecting Micro-Water in On-Line Oil Analysis

Abstract:

Molecular water in lubricants causes unavoidable damage in mechanical tribo-systems. To illustrate the characteristics of water in oil, three typical hybrid states, including dissolved, free, and emulsified states, were discussed focusing on the physical structures, hazards, and electric properties. Aiming at the on-line monitoring of molecular water in engine oil, a conductivity-based sensor was proposed. Two enamel wires, with partial naked surfaces, were winded around an insulated pole in parallel to serve as a probe. A higher cell constant was obtained with a high sensitivity. A multi-channel sensor with four probes was designed for on-line monitoring. The performance of the sensor was examined experimentally. As main result, the sensor has explicit effects on detecting free and emulsified water. The sensor also has a good linearity and repeatability when water content increasing from 0% to 3%, and has a high reliability under the disturbances of air and metal debris.

You might also be interested in these eBooks

Advances in Applied Sciences and Manufacturing

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 850-851)

Pages:

279-283

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.850-851.279

Citation:

Cite this paper

Online since:

December 2013

Authors:

Tong Hai Wu*, Ren Jie Gong, Xiao Gang Zhang, Chen Xing Sheng

Keywords:

Conductivity-Based, Emulsified Water, Enamel Wire-Wound Probe, Water-in-Oil

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] H. Chen: Development of a multi-functional portable instrument for marine hydraulic oil monitoring, (MS., Wuhan University of Technology, China 2010). In Chinese.

Google Scholar

[2] S.L. Wang: Research of Measuring Method on the TraceWater in Lubricating Oil, (MS., Northeastern University, China 2006). In Chinese.

Google Scholar

[3] M. Holzki, H. Fouckhardt and T. Klotzbücher: Sensors and Actuators A: Physical Sensors and Actuators A. Vol. 184 (2012), p.93.

DOI: 10.1016/j.sna.2012.07.005

Google Scholar

[4] Z.T. Lv, J. Cao, J.F. Ding and D. Yan: Chinese Journal of Scientific Instrument. Vol. 29 (2008) No. 9, p.1956. In Chinese.

Google Scholar

[5] Y.J. Li, C.H. Wang and H.X. Tian: Lubrication Engineering. Vol. 36 (2011) No. 9, p.107. In Chinese.

Google Scholar

[6] J.W. Xiao, D.X. Yang, Z. Hu and Y.M. Yang: Synthetic Lubricants. Vol. 36 (2009) No. 4, p.15. In Chinese.

Google Scholar

[7] D.D. Tang, L.G. Wang, J.C. Yang and H. Yan: Chinese Journal of Scientific Instrument. Vol. 25 (2004) No. 4, p.34. In Chinese.

Google Scholar

[8] Information on http: /www. vaisala. com/en/products/moistureinoil/Pages/MMT162. aspx.

Google Scholar

[9] Information on http: /www. epluse. com/en/products/moisture-in-oil-instrumentation.

Google Scholar

[10] L.M. Zhang, L.M. He, Y.L. Lv, Y.W. Song and Z.Y. He: Oilfield Chemistry. Vol. 25 (2008) No. 2, p.158. In Chinese.

Google Scholar

[11] H.F. Eicke, M. Borkovec and B. Das-Gupta: J Phys Chem. Vol. 93 (1989), p.314.

Google Scholar

[12] M.R.N. El-Din, I.M. El-Gamal, S.H. ElHamouly, H.M. Mohamed, M.R. Mishrif and A.M. Ragab: Colloids and Surface A: Physicochemical and Engineering Aspects (2013), http: /dx. doi. org/10. 1016/j. colsurfa. 2013. 06. 044.

DOI: 10.1016/j.colsurfa.2013.06.044

Google Scholar

[13] N. Kallay, M. Tomic and A. Chittofrati: Colloid & Polym Science. Vol. 270 (1992), p.194.

Google Scholar