In order to meet the requirements of high temperature acidizing, a new acid gelatinizer was synthesized by choosing non ionic monomer AM, complex cationic monomer H-DMDAAC, anionic monomer AMPS as starting materials and redox system as initiator in aqueous solution at low temperature. Various factors influencing polymerization reaction were analyzed, the optimum conditions of polymerization were determined, the basic performance of gelling acid was evaluated and its action mechanism was studied. The results show that it has good property to increase viscosity, resistance to high temperature and acid-rock reaction retardation, the viscosity of acidizing fluid of 20% mass fraction can reach 37.5 mPa·s at the high temperature of 150℃ and shearing rate of 170s-1 when the mass fraction of ZCY-1 is 1%; mass fraction of gelling acid remains 11.9% after 60 min’s reaction with limestone, which is 7 times more than that of common acid, it can meet the need of acidizing in high temperature wells.

Gao, J. C., Peng, Z., & Lin, H., et al. (2002). Synthesizing and performance test of XPI2-1 viscous acid’s thickener. Journal of Xinjiang Petroleum Institute, 12(4), 26-28.

Zou, Y. B., Zhou, L. B., & Pei, C., et al. (2003). Optimized research and application of slow reacting acid of high temperature and deep layer. Oil Drilling & Production Technology, 25(4), 61-63.

Ali, S. A. (2006). Effective stimulation of high-temperature sandstone formations in east venezuela with a new sandstone-acidizing system. SPE 98318.

Chike, U. (2004). Solvent/acid blend provides economic single step matrix acidizing success for fines and organic damage removal in sandstone reservoirs: A niger-delta case study. SPE 90798.

Pongratz, R. (2005). Optimizing matrix acid treatments in a multi-layered reservoir in Russia by applying different diversion techniques. SPE 94485.

Olav, M. (2004). Gelled organic acid system for improved CaCO₃ removal in horizontal openhole wells at the heidrun field. SPE 90359.