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Filtration Theory for Oil-Well Drilling Fluids

Published online by Cambridge University Press:  01 January 2024

D. T. Oakes
D. T. Oakes*
Affiliation:
Lion Oil Company, El Dorado, Arkansas, USA
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Abstract

In the oil industry it has been customary to describe water loss or filtration from benton-ite drilling fluids by adaptation of Darcy’s law to the filtration process. Thus, the rate of filtration varies directly with the differential pressure and permeability and inversely with the filtrate viscosity and the thickness of the deposited filter cake. Since the thickness of the filter cake is variable, however, it is necessary that the rate of deposition of the filter cake be related to the volume of filtrate. In establishing this relation certain workers have made questionable allowance for the water adsorbed on the bentonite particles with the result that the filtration equation is not valid in certain instances (Larsen, 1938; Rogers, 1953, p. 268).

Other workers have indicated the significance of the adsorbed phase in their presentation of experimental techniques for relating the filter cake and the filtrate (Williams and Cannon, 1938; von Englehardt, 1954).

The filtration relationship may be derived analytically by the simultaneous use of Darcy’s law and mass and volumetric balances on the filtration process. Such a derivation is here presented. The validity of the filtration relationship presented is experimentally confirmed using three groups of unlike systems—Wyoming bentonite suspensions, low-yield clay suspensions, and sodium carboxymethylcellulose suspensions—as well as four sets of clay filtration data from the literature.

Type
Article
Information
Clays and Clay Minerals (National Conference on Clays and Clay Minerals) , Volume 5 , February 1956 , pp. 46 - 60
Copyright
Copyright © Clay Minerals Society 1956

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References

Hauser, E. A., 1939, Colloidal phenomena: McGraw-Hill Book Company. Inc., New York, 294 p.Google Scholar
Larsen, H. D., 1938, Determining the filtration characteristics of drilling muds, Part 1: Petroleum Engineer, Sept., p. 4247; Part 2, Petroleum Engineer, Nov., p. 50-59.Google Scholar
MacEwan, D. M. C., 1955, Interlamellar sorption by clay minerals: in Clays and Clay Technology, California Division of Mines, Bull. 169, p. 7885.Google Scholar
Rogers, W. F., 1953, Composition and properties of oil well drilling fluids: Gulf Publishing Company, Houston, 676 p.Google Scholar
von Englehardt, W., 1954, Filter cake formation and water losses in deep drilling muds: Illinois State Geol. Survey, Circular 191, 24 p.Google Scholar
Williams, M., 1940, Radial filtration of drilling muds: AIME Trans., p. 5770.Google Scholar
Williams, M. and Cannon, G. E., 1938, Evaluation of filtration properties of drilling mud: API Drilling and Production Practice, p. 2028.Google Scholar