화학공학소재연구정보센터
Journal of Canadian Petroleum Technology, Vol.43, No.5, 41-48, 2004
Simulating cold production by a coupled reservoir-geomechanics model with sand erosion
A fully coupled reservoir-geomechanics model is developed to simulate the enhanced production phenomena both in heavy-oil reservoirs (i.e., Northwestern Canada) and conventional oil reservoirs (i.e., North Sea). The model is implemented numerically by fully coupling an extended geomechanics model to a two-phase reservoir flow model. A sand erosion model is postulated after the onset of sand production, which is determined based on the degree of plastic deformation inside the reservoir formation calculated by the coupled reservoir-geomechanics model. Both the enhanced oil production and the ranges of the enhanced or sanding zone are calculated, and the effect of solids production on oil recovery and enhancement are analyzed. Our studies indicate that the enhanced oil production can be the result of the combined effect of higher fluid velocity due to the movement of the sand particles according to a modified Darcy's flow and an effective permeability increase due to sand erosion. Another benefit from this process is that such an improvement in mobility may reduce the near well pressure gradient so that the sanding potential is reduced given a flow rate, and it permits a less sand-prone environment which is favorable for further sand control. In addition, two-phase flow can affect pressure gradient and formation residual cohesion due to capillary pressure change, which is also critical for sand control. Such an analogy can also be used for a completion strategy by allowing a certain amount of sand produced before a sand control strategy is implemented in a high flow-rate reservoir, when the optimum production is desirable, and when the reservoir productivity does not vitally rely on sand production. This article demonstrates the feasibility of such a model to simulate both sanding and enhanced oil production. Our initial attempt was to simulate the field performance in Northwestern Canada. As we were unable to match the field data using those input data for the onset of the stable sand production, we suggest that either new data is obtained for massive sand production (skeleton collapse), or such an erosion model should be used in the stable sanding period only, before the onset of massive sand production.