CIPC paper 2004–0491 described refinery plugging caused by volatile phosphorus components originating from phosphate ester oil gellants. Also documented were two successful field trials of new phosphonate ester oil gellants shown to address this problem.
CIPC paper 2005–0432 presented results of additional fieldtesting of phosphonate ester gellants directed at optimization of cost & performance.
A maximum 0.5 ppm volatile phosphorus in crude specification has been proposed to address costly unplanned refinery shutdowns. This specification is based on what is concidered achievable through a combination of new chemistry and typical field dilution. However, this specification is based on average concentrations of phosphorus added to the oil to gel it and assumes the oil is phosphorus free to begin with. In some flowback studies total and resulting volatile phosphorus concentrations greatly in excess of that added have been observed.
In addition, refinery plugging is more the result of total phosphorus throughput than peak concentrations at any one point. Therefore, an understanding of total phosphorus recovery in addition to peak concentrations is needed. The objectives of this paper are to study:
Total percent recovery of phosphorus originally added as phosphorus based gellant.
Total percent recovery of volatile phosphorus as a function of total phosphorus.
Peak concentrations of total and volatile phosphorus.
Phosphorus concentrations in new and reused fracturing fluids before addition of gellants.
Potential explanations for phosphorus concentrations significantly higher than those originally added.
Unconventional gas reservoirs including tight gas, shale gas, and coalbed methane are becoming critically important components of current and future gas supply. These reservoirs often present unique stimulation challenges. The use of waterbased fracturing fluids in low-permeability reservoirs may result in loss of effective fracture half-length caused by phase trapping associated with the retention of the introduced water-based fluid into the formation. This problem is increased by the water-wet nature of most tight gas reservoirs (where no initial liquid hydrocarbon saturation is or ever has been present) because of the strong spreading coefficient of water in such a situation.
The retention of this increased water saturation in the pore system can restrict the flow of produced gaseous hydrocarbons such as methane. Capillary pressures of 10–20 MPa or higher per thousand can be present in low-permeability formations at low water-saturation levels. The inability to generate sufficient capillary drawdown force using the natural reservoir drawdown pressure can result in extended fluid-recovery times or permanent loss of effective fracture half-length. Furthermore, use of water in subnormally saturated reservoirs may also reduce permeability and associated gas flow through a permanent increase in water saturation of the reservoir. Secondary costs such as rig time for swabbing can add to the negative economic impact.
The effects of fracturing fluid retention on gas flow in the fracture face can be as important a consideration as fracture conductivity when designing a treatment. It is possible to have a conductive fracture with good half-length in the desired productive zone and still not realize economic or optimum gas production if phase trapping and/or relative permeability effects are restricting gas flow.