Experimental and Modeling Study of Abrasive Wear of Tungsten Carbide Drilling Bit in Wet and Dry Conditions

محتوى المقالة الرئيسي

Fathi Al-Shammaa
Amar Hussein Al-Allaq
Mohaimen Habeeb Makki

الملخص

The results of theoretical and experimental investigations carried out to study the effect of load and relative sliding speed on the abrasive wear behavior in drilling bit teeth surfaces of an insert tungsten carbide bit have been presented. Experimentally, an apparatus for abrasive wear tests conducted on the modified ASTM-G65 was modified and fabricated to facilitate loading and measurement of wear rate for the sand/ steel wheel abrasion test, which involves two cases of contact; first is at dry sand and second is under wet condition. These tests have been carried under varied operating parameters of normal load and sliding speed. A theoretical model based upon the Archard equation has been developed for predicting wear simulation by using ANSYS12.1 program for dry and wet abrasive wear rates. The general trend for all the results of wet tests is that an increase in the applied load as well as wheel rotational speed produces an increase in wear rate, while at the dry tests the behavior shows an increase and fluctuating in wear rate due to the transition in wear mechanism. As compared to the dry tests, the volume losses in wet tests have much higher values, that is because the presence of water which causes high adhesion between sand particles and specimen surface as well as wear-corrosion interaction which accelerate the wear rates. The percentage errors between theoretical and experimental results are more stable with the wet than dry tests due to the stability in wear rates.

تفاصيل المقالة

القسم

Articles

كيفية الاقتباس

"Experimental and Modeling Study of Abrasive Wear of Tungsten Carbide Drilling Bit in Wet and Dry Conditions" (2014) مجلة الهندسة, 20(03), ص 51–61. doi:10.31026/j.eng.2014.03.05.

المراجع

A.J. Gant and M.G. Gee, 2001, Wear of Tungsten Carbide–Cobalt Hardmetals and Hot Isostatically Pressed High Speed Steels under Dry Abrasive Conditions, Wear 908–915.

Ameer Hussein Ali, 2008, Using Universal Material Tester to Study Effect of the Porosity on Wear Behavior, Master Thesis, University of Baghdad.

G. Raymond Bayer, 2004, Mechanical Wear Fundamentals, Second Edition, Vestal, New York.

K. Elalem and D.Y. Li 2001, Variations in Wear Loss with Respect to Load and Sliding Speed under Dry Sand/Rubber-Wheel Abrasion Condition: A Modeling Study, Wear 59–65.

Mandar Rajiv Thakare, 2008, Abrasion-Corrosion of Downhole Drill Tool Components, Ph.D. Thesis, University of Southampton.

M.John Thompson and Mary Kathryn Thompson ,2006, A Proposal for the Calculation of Wear, Mechanical Engineering Dept, MIT

G. Raymond Bayer, 2004, Mechanical Wear Fundamentals, Second Edition, Vestal, New York.

S. Wirojanupatump and P.H. Shipway, 2000, Abrasion of Mild Steel in Wet and Dry Conditions with the Rubber and Steel Wheel Abrasion Apparatus, Wear 91–101.

Tatjana Lazovic, Radivoje Mitrovic and Mileta Ristivojevic, 2003, Influence of Abrasive Particle Geometry and Material on the Abrasive Wear Mode, University of Belgrade.

X. Ma, R. Liu and D.Y. Li, 2000, Abrasive Wear Behavior of D2 Tool Steel with Respect to Load and Sliding Speed under Dry Sand/Rubber Wheel Abrasion Condition, Wear 79–85.

المؤلفات المشابهة

يمكنك أيضاً إبدأ بحثاً متقدماً عن المشابهات لهذا المؤلَّف.