Perfluorinated chemicals (PFCs) are common substances used in daily life and industrial processes. Long-chain PFCs were widely used in the past, but as their toxicity and persistence have been revealed, many countries have gradually banned their use and replaced them with short-chain PFCs, such as Perfluorobutanesulfonic Acid (PFBS). However, studies have indicated that short-chain PFCs also exhibit toxicity and persistence, making the study of the removal of short-chain PFCs important. This study utilizes ion exchange resin (IRA402) to remove PFBS from water. The zeta potential, surface structure, elemental composition, chemical bonds, and functional groups of the ion exchange resin were analyzed, and the effects of PFBS initial concentration, ion exchange resin dosage, stirring rate, and solution pH on the removal efficiency were investigated to determine the optimal experimental parameters. Under these conditions, cationic surfactants (DTAB, TBAB) and anionic surfactants (SDS) were added to explore the effect of surfactant on the ion exchange efficiency. The results showed that with an initial PFBS concentration of 25 ppm, solution pH of 3, room temperature, stirring speed of 400 rpm, and ion exchange resin dosage of 2 g/L, the addition of 1 mM TBAB resulted in the best performance, achieving a 100% removal rate within 30 minutes, 10 minutes shorter than without surfactant addition, with an exchange capacity of 12.94 mg/g. The removal rate could be increased by 20.86% within 5 minutes. The addition of TBAB improved the exchange rate across different initial PFBS concentrations. At an initial PFBS concentration of 100 ppm, with other experimental parameters unchanged, the addition of 1 mM SDS had a negative impact, leading to longer reaction time and lower removal rate. The reaction kinetics modeling results indicated that experiments followed the pseudo-first-order reaction kinetics model.