Abstract

The paper will present the field test results of two electromagnetic (EM) stimulation projects conducted in the L1oydl1linster heavy oil area. The two wells (AI-1l-48-25 W3M Lashbum and AS-6051-27 W3M Northminster) produce heavy crude from the Sparky formation. Detailed production, electrical and operational data was gathered and analyzed to quantify the effect EM stimulation had on each well's producing characteristics.

77Je main areas covered by the paper include production characteristics (primary and enhanced), inflow performance relationships (primary and enhanced), operational considerations and some of the related economics. The data discussed to this point has been restricted to reservoir heating.

An additional review of a tubing heating electrical configuration test (ran on the Lashbum well) has been included. 17ze viscous nature of the crude oil being produced caused severe rod fall problems. Tubing heating was initiated to reduce the wellbore fluid viscosity and eliminate the rod fall problem. The paper will conclude with a general overview of the EM stimulation process as applied to the Canada Northwest Energy Limited locations and the potential for future applications.

Introduction

The possibility of using electrical energy to heat oil bearing formations has been attempted on several occasions over the past four decades. In general terms, the electrical (and electromagnetic energy) is converted to heat. Three basic types of heating are possible (dielectric, inductive and resistive). This discussion will deal with the resistive heating process.

Canada Northwest Energy et al (CNW) contracted with EOR International (EOR) to field test the process in the Lloydminster area heavy oil formations. A majority of the heavy oil sands around Lloydminster are well suited to the application of electromagnetic (EM) heating. Many of the formations are relatively thin and not well suited for other secondary, tertiary and thermal recovery methods. The EM heating process as applied in the CNW pilot areas creates a heated zone in the near wellbore region. The application of heat significantly reduces the viscosity of the oil, improves the oil/water flow characteristics, and overcomes some forms of formation damage. The end result is an improved pressure profile in the near wellbore region and a corresponding increase in the oil production rate.

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