Organic electrochemical transistor (OECT) devices demonstrate great promising potential for reservoir computing (RC) systems, but their lack of tunable dynamic characteristics limits their application in multi-temporal scale tasks. In this study, we report an OECT-based neuromorphic device with tunable relaxation time (τ) by introducing an additional vertical back-gate electrode into a planar structure. The dual-gate design enables τ reconfiguration from 93 to 541 ms. The tunable relaxation behaviors can be attributed to the combined effects of planar-gate induced electrochemical doping and back-gate-induced electrostatic coupling, as verified by electrochemical impedance spectroscopy analysis. Furthermore, we used the τ-tunable OECT devices as physical reservoirs in the RC system for intelligent driving trajectory prediction, achieving a significant improvement in prediction accuracy from below 69% to 99%. The results demonstrate that the τ-tunable OECT shows a promising candidate for multi-temporal scale neuromorphic computing applications.