Quantum secret sharing (QSS) is a cryptography technique relying on the transmission and manipulation of quantum states to distribute secret information across multiple participants securely. However, quantum systems are susceptible to various types of noise that can compromise their security and reliability. Therefore, it is essential to analyze the influence of noise on QSS to ensure their effectiveness and practicality in real-world quantum communication. This paper studies the impact of various noisy environments on multi-dimensional QSS. Using quantum fidelity, we examine the influence of four noise models: d-phase-flip(dpf), dit-flip(df), amplitude damping(ad), and depolarizing(d). It has been discovered that the fidelity declines with an increase in the noise parameter. Furthermore, the results demonstrate that the efficiency of the QSS protocol differs significantly across distinct noise models.